how can students improve problem solving skills

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Strategies to develop problem-solving skills in students.

November 14, 2023

OWIS Nanyang | Secondary Students in Maths Lesson | Problem-Solving Skills | International School in Singapore

Students need the freedom to brainstorm, develop solutions and make mistakes — this is truly the only way to prepare them for life outside the classroom. When students are immersed in a learning environment that only offers them step-by-step guides and encourages them to focus solely on memorisation, they are not gaining the skills necessary to help them navigate in the complex, interconnected environment of the real world.

Choosing a school that emphasises the importance of future-focussed skills will ensure your child has the abilities they need to survive and thrive anywhere in the world. What are future-focussed skills? Students who are prepared for the future need to possess highly developed communication skills, self-management skills, research skills, thinking skills, social skills and problem-solving skills. In this blog, I would like to focus on problem-solving skills.

What Are Problem-Solving Skills?

The Forage defines problem-solving skills as those that allow an individual to identify a problem, come up with solutions, analyse the options and collaborate to find the best solution for the issue.

Importance of Problem-Solving in the Classroom Setting

Learning how to solve problems effectively and positively is a crucial part of child development. When children are allowed to solve problems in a classroom setting, they can test those skills in a safe and nurturing environment. Generally, when they face age-appropriate issues, they can begin building those skills in a healthy and positive manner.

Without exposure to challenging situations and scenarios, children will not be equipped with the foundational problem-solving skills needed to tackle complex issues in the real world. Experts predict that problem-solving skills will eventually be more sought after in job applicants than hard skills related to that specific profession. Students must be given opportunities in school to resolve conflicts, address complex problems and come up with their own solutions in order to develop these skills.

Benefits of Problem-Solving Skills for Students

how can students improve problem solving skills

Learning how to solve problems offers students many advantages, such as:

Improving Academic Results

When students have a well-developed set of problem-solving skills, they are often better critical and analytical thinkers as well. They are able to effectively use these 21st-century skills when completing their coursework, allowing them to become more successful in all academic areas. By prioritising problem-solving strategies in the classroom, teachers often find that academic performance improves.

Developing Confidence

Giving students the freedom to solve problems and create their own solutions is essentially permitting them to make their own choices. This sense of independence — and the natural resilience that comes with it — allows students to become confident learners who aren’t intimidated by new or challenging situations. Ultimately, this prepares them to take on more complex challenges in the future, both on a professional and social level.

Preparing Students for Real-World Challenges

The challenges we are facing today are only growing more complex, and by the time students have graduated, they are going to be facing issues that we may not even have imagined. By arming them with real-world problem-solving experience, they will not feel intimidated or stifled by those challenges; they will be excited and ready to address them. They will know how to discuss their ideas with others, respect various perspectives and collaborate to develop a solution that best benefits everyone involved.

The Best Problem-Solving Strategies for Students

No single approach or strategy will instil a set of problem-solving skills in students. Every child is different, so educators should rely on a variety of strategies to develop this core competency in their students. It is best if these skills are developed naturally.

These are some of the best strategies to support students problem-solving skills:

Project-Based Learning

By providing students with project-based learning experiences and allowing plenty of time for discussion, educators can watch students put their problem-solving skills into action inside their classrooms. This strategy is one of the most effective ways to fine-tune problem-solving skills in students. During project-based learning, teachers may take notes on how the students approach a problem and then offer feedback to students for future development. Teachers can address their observations of interactions during project-based learning at the group level or they can work with students on an individual basis to help them become more effective problem-solvers.

Encourage Discussion and Collaboration in the Classroom Setting

Another strategy to encourage the development of problem-solving skills in students is to allow for plenty of discussion and collaboration in the classroom setting. When students interact with one another, they are naturally developing problem solving skills. Rather than the teacher delivering information and requiring the students to passively receive information, students can share thoughts and ideas with one another. Getting students to generate their own discussion and communication requires thinking skills.

Utilising an Inquiry-Based approach to Learning

Students should be presented with situations in which their curiosity is sparked and they are motivated to inquire further. Teachers should ask open-ended questions and encourage students to develop responses which require problem-solving. By providing students with complex questions for which a variety of answers may be correct, teachers get students to consider different perspectives and deal with potential disagreement, which requires problem-solving skills to resolve.

Model Appropriate Problem-Solving Skills

One of the simplest ways to instil effective problem-solving skills in students is to model appropriate and respectful strategies and behaviour when resolving a conflict or addressing an issue. Teachers can showcase their problem-solving skills by:

Identifying a problem when they come across one for the class to see
Brainstorming possible solutions with students
Collaborating with students to decide on the best solution
Testing that solution and examining the results with the students
Adapting as necessary to improve results or achieve the desired goal

Prioritise Student Agency in Learning

Recent research shows that self-directed learning is one of the most effective ways to nurture 21st-century competency development in young learners. Learning experiences that encourage student agency often require problem-solving skills. When creativity and innovation are needed, students often encounter unexpected problems along the way that must be solved. Through self-directed learning, students experience challenges in a natural situation and can fine-tune their problem-solving skills along the way. Self-directed learning provides them with a foundation in problem-solving that they can build upon in the future, allowing them to eventually develop more advanced and impactful problem-solving skills for real life.

21st-Century Skill Development at OWIS Singapore

Problem-solving has been identified as one of the core competencies that young learners must develop to be prepared to meet the dynamic needs of a global environment. At OWIS Singapore, we have implemented an inquiry-driven, skills-based curriculum that allows students to organically develop critical future-ready skills — including problem-solving. Our hands-on approach to education enables students to collaborate, explore, innovate, face-challenges, make mistakes and adapt as necessary. As such, they learn problem-solving skills in an authentic manner.

For more information about 21st-century skill development, schedule a campus tour today.

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Developing Problem-Solving Skills for Kids | Strategies & Tips

We've made teaching problem-solving skills for kids a whole lot easier! Keep reading and comment below with any other tips you have for your classroom!

Problem-Solving Skills for Kids: The Real Deal

Picture this: You've carefully created an assignment for your class. The step-by-step instructions are crystal clear. During class time, you walk through all the directions, and the response is awesome. Your students are ready! It's finally time for them to start working individually and then... 8 hands shoot up with questions. You hear one student mumble in the distance, "Wait, I don't get this" followed by the dreaded, "What are we supposed to be doing again?"

When I was a new computer science teacher, I would have this exact situation happen. As a result, I would end up scrambling to help each individual student with their problems until half the class period was eaten up. I assumed that in order for my students to learn best, I needed to be there to help answer questions immediately so they could move forward and complete the assignment.

Here's what I wish I had known when I started teaching coding to elementary students - the process of grappling with an assignment's content can be more important than completing the assignment's product. That said, not every student knows how to grapple, or struggle, in order to get to the "aha!" moment and solve a problem independently. The good news is, the ability to creatively solve problems is not a fixed skill. It can be learned by students, nurtured by teachers, and practiced by everyone!

Your students are absolutely capable of navigating and solving problems on their own. Here are some strategies, tips, and resources that can help:

Problem-Solving Skills for Kids: Student Strategies

These are strategies your students can use during independent work time to become creative problem solvers.

1. Go Step-By-Step Through The Problem-Solving Sequence

Post problem-solving anchor charts and references on your classroom wall or pin them to your Google Classroom - anything to make them accessible to students. When they ask for help, invite them to reference the charts first.

Problem-solving skills for kids made easy using the problem solving sequence.

2. Revisit Past Problems

If a student gets stuck, they should ask themself, "Have I ever seen a problem like this before? If so, how did I solve it?" Chances are, your students have tackled something similar already and can recycle the same strategies they used before to solve the problem this time around.

3. Document What Doesn’t Work

Sometimes finding the answer to a problem requires the process of elimination. Have your students attempt to solve a problem at least two different ways before reaching out to you for help. Even better, encourage them write down their "Not-The-Answers" so you can see their thought process when you do step in to support. Cool thing is, you likely won't need to! By attempting to solve a problem in multiple different ways, students will often come across the answer on their own.

4. "3 Before Me"

Let's say your students have gone through the Problem Solving Process, revisited past problems, and documented what doesn't work. Now, they know it's time to ask someone for help. Great! But before you jump into save the day, practice "3 Before Me". This means students need to ask 3 other classmates their question before asking the teacher. By doing this, students practice helpful 21st century skills like collaboration and communication, and can usually find the info they're looking for on the way.

Problem-Solving Skills for Kids: Teacher Tips

These are tips that you, the teacher, can use to support students in developing creative problem-solving skills for kids.

1. Ask Open Ended Questions

When a student asks for help, it can be tempting to give them the answer they're looking for so you can both move on. But what this actually does is prevent the student from developing the skills needed to solve the problem on their own. Instead of giving answers, try using open-ended questions and prompts. Here are some examples:

2. Encourage Grappling

Grappling is everything a student might do when faced with a problem that does not have a clear solution. As explained in this article from Edutopia , this doesn't just mean perseverance! Grappling is more than that - it includes critical thinking, asking questions, observing evidence, asking more questions, forming hypotheses, and constructing a deep understanding of an issue.

There are lots of ways to provide opportunities for grappling. Anything that includes the Engineering Design Process is a good one! Examples include:

Engineering or Art Projects
Design-thinking challenges
Computer science projects
Science experiments

3. Emphasize Process Over Product

For elementary students, reflecting on the process of solving a problem helps them develop a growth mindset . Getting an answer "wrong" doesn't need to be a bad thing! What matters most are the steps they took to get there and how they might change their approach next time. As a teacher, you can support students in learning this reflection process.

4. Model The Strategies Yourself!

As creative problem-solving skills for kids are being learned, there will likely be moments where they are frustrated or unsure. Here are some easy ways you can model what creative problem-solving looks and sounds like.

Ask clarifying questions if you don't understand something
Admit when don't know the correct answer
Talk through multiple possible outcomes for different situations
Verbalize how you’re feeling when you find a problem

Practicing these strategies with your students will help create a learning environment where grappling, failing, and growing is celebrated!

Problem-Solving Skill for Kids

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College Minor: Everything You Need to Know

14 fascinating teacher interview questions for principals, tips for success if you have a master’s degree and can’t find a job, 14 ways young teachers can get that professional look, which teacher supplies are worth the splurge, 8 business books every teacher should read, conditional admission: everything you need to know, college majors: everything you need to know, 7 things principals can do to make a teacher observation valuable, 3 easy teacher outfits to tackle parent-teacher conferences, strategies and methods to teach students problem solving and critical thinking skills.

The ability to problem solve and think critically are two of the most important skills that PreK-12 students can learn. Why? Because students need these skills to succeed in their academics and in life in general. It allows them to find a solution to issues and complex situations that are thrown there way, even if this is the first time they are faced with the predicament.

Okay, we know that these are essential skills that are also difficult to master. So how can we teach our students problem solve and think critically? I am glad you asked. In this piece will list and discuss strategies and methods that you can use to teach your students to do just that.

Direct Analogy Method

A method of problem-solving in which a problem is compared to similar problems in nature or other settings, providing solutions that could potentially be applied.

Attribute Listing

A technique used to encourage creative thinking in which the parts of a subject, problem, or task are listed, and then ways to change those component parts are examined.

Attribute Modifying

A technique used to encourage creative thinking in which the parts of a subject, problem, or task are listed, and then options for changing or improving each part are considered.

Attribute Transferring

A technique used to encourage creative thinking in which the parts of a subject, problem or task listed and then the problem solver uses analogies to other contexts to generate and consider potential solutions.

Morphological Synthesis

A technique used to encourage creative problem solving which extends on attribute transferring. A matrix is created, listing concrete attributes along the x-axis, and the ideas from a second attribute along with the y-axis, yielding a long list of idea combinations.

SCAMPER stands for Substitute, Combine, Adapt, Modify-Magnify-Minify, Put to other uses, and Reverse or Rearrange. It is an idea checklist for solving design problems.

Direct Analogy

A problem-solving technique in which an individual is asked to consider the ways problems of this type are solved in nature.

Personal Analogy

A problem-solving technique in which an individual is challenged to become part of the problem to view it from a new perspective and identify possible solutions.

Fantasy Analogy

A problem-solving process in which participants are asked to consider outlandish, fantastic or bizarre solutions which may lead to original and ground-breaking ideas.

Symbolic Analogy

A problem-solving technique in which participants are challenged to generate a two-word phrase related to the design problem being considered and that appears self-contradictory. The process of brainstorming this phrase can stimulate design ideas.

Implementation Charting

An activity in which problem solvers are asked to identify the next steps to implement their creative ideas. This step follows the idea generation stage and the narrowing of ideas to one or more feasible solutions. The process helps participants to view implementation as a viable next step.

Thinking Skills

Skills aimed at aiding students to be critical, logical, and evaluative thinkers. They include analysis, comparison, classification, synthesis, generalization, discrimination, inference, planning, predicting, and identifying cause-effect relationships.

Can you think of any additional problems solving techniques that teachers use to improve their student’s problem-solving skills?

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Don’t Just Tell Students to Solve Problems. Teach Them How.

The positive impact of an innovative uc san diego problem-solving educational curriculum continues to grow.

Daniel Kane - [email protected]

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Not getting stuck

One of the overarching goals of this project is to teach both problem-identification and problem-solving skills that help students avoid getting stuck during the learning process. Stuck feelings lead to frustration – and when it’s a Science, Technology, Engineering and Math (STEM) project, that frustration can lead students to feel they don’t belong in a STEM major or a STEM career. Instead, the UC San Diego curriculum is designed to give students the tools that lead to reactions like “this class is hard, but I know I can do this!” – as Ogo, a celebrated high school biomedical sciences and technology teacher, put it.

Three years into the curriculum development effort, the light-hearted energy of the students combined with their intense focus points to success. On the last day of the class, Mourad Mjahed PhD, Director of the MESA Program at Southwestern College’s School of Mathematics, Science and Engineering came to UC San Diego to see the final project presentations made by his 22 MESA students.

“Industry is looking for students who have learned from their failures and who have worked outside of their comfort zones,” said Mjahed. The UC San Diego problem-solving curriculum, Mjahed noted, is an opportunity for students to build the skills and the confidence to learn from their failures and to work outside their comfort zone. “And from there, they see pathways to real careers,” he said.

What does it mean to explicitly teach problem solving?

This approach to teaching problem solving includes a significant focus on learning to identify the problem that actually needs to be solved, in order to avoid solving the wrong problem. The curriculum is organized so that each day is a complete experience. It begins with the teacher introducing the problem-identification or problem-solving strategy of the day. The teacher then presents case studies of that particular strategy in action. Next, the students get introduced to the day’s challenge project. Working in teams, the students compete to win the challenge while integrating the day’s technique. Finally, the class reconvenes to reflect. They discuss what worked and didn't work with their designs as well as how they could have used the day’s problem-identification or problem-solving technique more effectively.

The challenges are designed to be engaging – and over three years, they have been refined to be even more engaging. But the student engagement is about much more than being entertained. Many of the students recognize early on that the problem-identification and problem-solving skills they are learning can be applied not just in the classroom, but in other classes and in life in general.

Gabriel from Southwestern College is one of the students who saw benefits outside the classroom almost immediately. In addition to taking the UC San Diego problem-solving course, Gabriel was concurrently enrolled in an online computer science programming class. He said he immediately started applying the UC San Diego problem-identification and troubleshooting strategies to his coding assignments.

Gabriel noted that he was given a coding-specific troubleshooting strategy in the computer science course, but the more general problem-identification strategies from the UC San Diego class had been extremely helpful. It’s critical to “find the right problem so you can get the right solution. The strategies here,” he said, “they work everywhere.”

Phan echoed this sentiment. “We believe this curriculum can prepare students for the technical workforce. It can prepare students to be impactful for any career path.”

The goal is to be able to offer the course in community colleges for course credit that transfers to the UC, and to possibly offer a version of the course to incoming students at UC San Diego.

As the team continues to work towards integrating the curriculum in both standardized high school courses such as physics, and incorporating the content as a part of the general education curriculum at UC San Diego, the project is expected to impact thousands more students across San Diego annually.

Portrait of the Problem-Solving Curriculum

On a sunny Wednesday in July 2023, an experiential-learning classroom was full of San Diego community college students. They were about half-way through the three-week problem-solving course at UC San Diego, held in the campus’ EnVision Arts and Engineering Maker Studio. On this day, the students were challenged to build a contraption that would propel at least six ping pong balls along a kite string spanning the laboratory. The only propulsive force they could rely on was the air shooting out of a party balloon.

A team of three students from Southwestern College – Valeria, Melissa and Alondra – took an early lead in the classroom competition. They were the first to use a plastic bag instead of disposable cups to hold the ping pong balls. Using a bag, their design got more than half-way to the finish line – better than any other team at the time – but there was more work to do.

As the trio considered what design changes to make next, they returned to the problem-solving theme of the day: unintended consequences. Earlier in the day, all the students had been challenged to consider unintended consequences and ask questions like: When you design to reduce friction, what happens? Do new problems emerge? Did other things improve that you hadn’t anticipated?

Other groups soon followed Valeria, Melissa and Alondra’s lead and began iterating on their own plastic-bag solutions to the day’s challenge. New unintended consequences popped up everywhere. Switching from cups to a bag, for example, reduced friction but sometimes increased wind drag.

Over the course of several iterations, Valeria, Melissa and Alondra made their bag smaller, blew their balloon up bigger, and switched to a different kind of tape to get a better connection with the plastic straw that slid along the kite string, carrying the ping pong balls.

One of the groups on the other side of the room watched the emergence of the plastic-bag solution with great interest.

“We tried everything, then we saw a team using a bag,” said Alexander, a student from City College. His team adopted the plastic-bag strategy as well, and iterated on it like everyone else. They also chose to blow up their balloon with a hand pump after the balloon was already attached to the bag filled with ping pong balls – which was unique.

“I don’t want to be trying to put the balloon in place when it's about to explode,” Alexander explained.

Asked about whether the structured problem solving approaches were useful, Alexander’s teammate Brianna, who is a Southwestern College student, talked about how the problem-solving tools have helped her get over mental blocks. “Sometimes we make the most ridiculous things work,” she said. “It’s a pretty fun class for sure.”

Yoshadara, a City College student who is the third member of this team, described some of the problem solving techniques this way: “It’s about letting yourself be a little absurd.”

Alexander jumped back into the conversation. “The value is in the abstraction. As students, we learn to look at the problem solving that worked and then abstract out the problem solving strategy that can then be applied to other challenges. That’s what mathematicians do all the time,” he said, adding that he is already thinking about how he can apply the process of looking at unintended consequences to improve both how he plays chess and how he goes about solving math problems.

Looking ahead, the goal is to empower as many students as possible in the San Diego area and beyond to learn to problem solve more enjoyably. It’s a concrete way to give students tools that could encourage them to thrive in the growing number of technical careers that require sharp problem-solving skills, whether or not they require a four-year degree.

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Teaching problem solving.

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Tips and Techniques

Expert vs. novice problem solvers, communicate.

Have students identify specific problems, difficulties, or confusions . Don’t waste time working through problems that students already understand.
If students are unable to articulate their concerns, determine where they are having trouble by asking them to identify the specific concepts or principles associated with the problem.
In a one-on-one tutoring session, ask the student to work his/her problem out loud . This slows down the thinking process, making it more accurate and allowing you to access understanding.
When working with larger groups you can ask students to provide a written “two-column solution.” Have students write up their solution to a problem by putting all their calculations in one column and all of their reasoning (in complete sentences) in the other column. This helps them to think critically about their own problem solving and helps you to more easily identify where they may be having problems. Two-Column Solution (Math) Two-Column Solution (Physics)

Encourage Independence

Model the problem solving process rather than just giving students the answer. As you work through the problem, consider how a novice might struggle with the concepts and make your thinking clear
Have students work through problems on their own. Ask directing questions or give helpful suggestions, but provide only minimal assistance and only when needed to overcome obstacles.
Don’t fear group work ! Students can frequently help each other, and talking about a problem helps them think more critically about the steps needed to solve the problem. Additionally, group work helps students realize that problems often have multiple solution strategies, some that might be more effective than others

Be sensitive

Frequently, when working problems, students are unsure of themselves. This lack of confidence may hamper their learning. It is important to recognize this when students come to us for help, and to give each student some feeling of mastery. Do this by providing positive reinforcement to let students know when they have mastered a new concept or skill.

Encourage Thoroughness and Patience

Try to communicate that the process is more important than the answer so that the student learns that it is OK to not have an instant solution. This is learned through your acceptance of his/her pace of doing things, through your refusal to let anxiety pressure you into giving the right answer, and through your example of problem solving through a step-by step process.

Experts (teachers) in a particular field are often so fluent in solving problems from that field that they can find it difficult to articulate the problem solving principles and strategies they use to novices (students) in their field because these principles and strategies are second nature to the expert. To teach students problem solving skills, a teacher should be aware of principles and strategies of good problem solving in his or her discipline .

The mathematician George Polya captured the problem solving principles and strategies he used in his discipline in the book How to Solve It: A New Aspect of Mathematical Method (Princeton University Press, 1957). The book includes a summary of Polya’s problem solving heuristic as well as advice on the teaching of problem solving.

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Practice makes perfect, but mix it up

By Fraser Scott 2022-03-24T08:30:00+00:00

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Does question bank design affect student performance?

We know it is important to provide students with repeated opportunities to practise solving questions. In a new study, researchers examined how the presentation and format of practice questions influences students’ problem-solving performance. The study revealed that mixed problem sets are better than questions arranged by topic.

There are two types of question practice teachers can give their students. The first, blocked practice, involves solving multiple problems of the same type, or about the same concept, before moving on to another. Practice worksheets and end-of-chapter questions in textbooks are often blocked practice type questions. They hone students’ algorithmic problem-solving skills, but at the expense of their conceptual understanding of the topic. The second, interleaved practice, shuffles between different types of questions in one session. It is more difficult, because students must identify the type of question being asked, or the concept it relates to, in addition to answering. Shuffled questions are thought to help with long-term learning and are similar to the questioning format in students’ exams.

The researchers investigated the effects of these two kinds of practice. They recruited 79 university students from general chemistry classes. They gave one group assignments with mixed questions and a control group assignments with questions organised into topics or chapters. They compared the groups’ performances through one pre-test and post-test after each of three problem-solving sessions.

Teaching tips

Source or compile more mixed practice question banks, and avoid solely using topic-specific question sets from textbooks.
To increase the difficulty and benefits of mixed problem question sets, do not include details identifying the relevant topics or chapters.
Blocked practice still has a place. Certain topics, particularly those to do with numerical problem-solving, may require extensive blocked practice before students can engage with the benefits of interleaved practice.

Probing the problems

Rather than looking at overall scores, the researchers used a more detailed analysis. They broke each problem into the sub-problems, or steps, required to answer the problem. They then categorised students’ answers to the steps as successful, neutral or unsuccessful. Subcategories provided more insight into the students’ work. For example, the neutral category contained the subcategories ‘not required’, ‘did not know to do’ and ‘did something else’.

The study revealed that students in the interleaved-practice group increased their problem-solving success more than those in the blocked-practice group. Significantly, the achievement gap between the experimental and control groups widened as the study progressed. Following interleaved practice, students’ neutral codes decreased by about 70%, unsuccessful codes decreased by about 40%, and the successful codes increased by about 52%. Even if students were not able to complete the entire problem, they still improved at individual steps.

Importantly, even though A-, B- and C-grade students showed different levels of improvement, they all benefited from interleaved practice. Perhaps unexpectedly, B- and C-grade students improved the most. This might relate to their poorer conceptual understanding of topics or assessment literacy beforehand, which interleaved practice helps to develop.

Fraser Scott

O. Gulacar et al, Chem. Educ. Res. Pract., 2022, DOI: 10.1039/D1RP00334H

O. Gulacar et al, Chem. Educ. Res. Pract., 2022, 23 , 422–435 ( DOI: 10.1039/D1RP00334H )

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Why Every Educator Needs to Teach Problem-Solving Skills

Strong problem-solving skills will help students be more resilient and will increase their academic and career success .

Want to learn more about how to measure and teach students’ higher-order skills, including problem solving, critical thinking, and written communication?

Problem-solving skills are essential in school, careers, and life.

Problem-solving skills are important for every student to master. They help individuals navigate everyday life and find solutions to complex issues and challenges. These skills are especially valuable in the workplace, where employees are often required to solve problems and make decisions quickly and effectively.

Problem-solving skills are also needed for students’ personal growth and development because they help individuals overcome obstacles and achieve their goals. By developing strong problem-solving skills, students can improve their overall quality of life and become more successful in their personal and professional endeavors.

Problem-Solving Skills Help Students…

develop resilience.

Problem-solving skills are an integral part of resilience and the ability to persevere through challenges and adversity. To effectively work through and solve a problem, students must be able to think critically and creatively. Critical and creative thinking help students approach a problem objectively, analyze its components, and determine different ways to go about finding a solution.

This process in turn helps students build self-efficacy . When students are able to analyze and solve a problem, this increases their confidence, and they begin to realize the power they have to advocate for themselves and make meaningful change.

When students gain confidence in their ability to work through problems and attain their goals, they also begin to build a growth mindset . According to leading resilience researcher, Carol Dweck, “in a growth mindset, people believe that their most basic abilities can be developed through dedication and hard work—brains and talent are just the starting point. This view creates a love of learning and a resilience that is essential for great accomplishment.”

Set and Achieve Goals

Students who possess strong problem-solving skills are better equipped to set and achieve their goals. By learning how to identify problems, think critically, and develop solutions, students can become more self-sufficient and confident in their ability to achieve their goals. Additionally, problem-solving skills are used in virtually all fields, disciplines, and career paths, which makes them important for everyone. Building strong problem-solving skills will help students enhance their academic and career performance and become more competitive as they begin to seek full-time employment after graduation or pursue additional education and training.

Resolve Conflicts

In addition to increased social and emotional skills like self-efficacy and goal-setting, problem-solving skills teach students how to cooperate with others and work through disagreements and conflicts. Problem-solving promotes “thinking outside the box” and approaching a conflict by searching for different solutions. This is a very different (and more effective!) method than a more stagnant approach that focuses on placing blame or getting stuck on elements of a situation that can’t be changed.

While it’s natural to get frustrated or feel stuck when working through a conflict, students with strong problem-solving skills will be able to work through these obstacles, think more rationally, and address the situation with a more solution-oriented approach. These skills will be valuable for students in school, their careers, and throughout their lives.

Achieve Success

We are all faced with problems every day. Problems arise in our personal lives, in school and in our jobs, and in our interactions with others. Employers especially are looking for candidates with strong problem-solving skills. In today’s job market, most jobs require the ability to analyze and effectively resolve complex issues. Students with strong problem-solving skills will stand out from other applicants and will have a more desirable skill set.

In a recent opinion piece published by The Hechinger Report , Virgel Hammonds, Chief Learning Officer at KnowledgeWorks, stated “Our world presents increasingly complex challenges. Education must adapt so that it nurtures problem solvers and critical thinkers.” Yet, the “traditional K–12 education system leaves little room for students to engage in real-world problem-solving scenarios.” This is the reason that a growing number of K–12 school districts and higher education institutions are transforming their instructional approach to personalized and competency-based learning, which encourage students to make decisions, problem solve and think critically as they take ownership of and direct their educational journey.

Problem-Solving Skills Can Be Measured and Taught

Research shows that problem-solving skills can be measured and taught. One effective method is through performance-based assessments which require students to demonstrate or apply their knowledge and higher-order skills to create a response or product or do a task.

What Are Performance-Based Assessments?

With the No Child Left Behind Act (2002), the use of standardized testing became the primary way to measure student learning in the U.S. The legislative requirements of this act shifted the emphasis to standardized testing, and this led to a decline in nontraditional testing methods .

But many educators, policy makers, and parents have concerns with standardized tests. Some of the top issues include that they don’t provide feedback on how students can perform better, they don’t value creativity, they are not representative of diverse populations, and they can be disadvantageous to lower-income students.

While standardized tests are still the norm, U.S. Secretary of Education Miguel Cardona is encouraging states and districts to move away from traditional multiple choice and short response tests and instead use performance-based assessment, competency-based assessments, and other more authentic methods of measuring students abilities and skills rather than rote learning.

Performance-based assessments measure whether students can apply the skills and knowledge learned from a unit of study. Typically, a performance task challenges students to use their higher-order skills to complete a project or process. Tasks can range from an essay to a complex proposal or design.

Preview a Performance-Based Assessment

Want a closer look at how performance-based assessments work? Preview CAE’s K–12 and Higher Education assessments and see how CAE’s tools help students develop critical thinking, problem-solving, and written communication skills.

Performance-Based Assessments Help Students Build and Practice Problem-Solving Skills

In addition to effectively measuring students’ higher-order skills, including their problem-solving skills, performance-based assessments can help students practice and build these skills. Through the assessment process, students are given opportunities to practically apply their knowledge in real-world situations. By demonstrating their understanding of a topic, students are required to put what they’ve learned into practice through activities such as presentations, experiments, and simulations.

This type of problem-solving assessment tool requires students to analyze information and choose how to approach the presented problems. This process enhances their critical thinking skills and creativity, as well as their problem-solving skills. Unlike traditional assessments based on memorization or reciting facts, performance-based assessments focus on the students’ decisions and solutions, and through these tasks students learn to bridge the gap between theory and practice.

Performance-based assessments like CAE’s College and Career Readiness Assessment (CRA+) and Collegiate Learning Assessment (CLA+) provide students with in-depth reports that show them which higher-order skills they are strongest in and which they should continue to develop. This feedback helps students and their teachers plan instruction and supports to deepen their learning and improve their mastery of critical skills.

Explore CAE’s Problem-Solving Assessments

CAE offers performance-based assessments that measure student proficiency in higher-order skills including problem solving, critical thinking, and written communication.

College and Career Readiness Assessment (CCRA+) for secondary education and
Collegiate Learning Assessment (CLA+) for higher education.

Our solution also includes instructional materials, practice models, and professional development.

We can help you create a program to build students’ problem-solving skills that includes:

Measuring students’ problem-solving skills through a performance-based assessment
Using the problem-solving assessment data to inform instruction and tailor interventions
Teaching students problem-solving skills and providing practice opportunities in real-life scenarios
Supporting educators with quality professional development

Get started with our problem-solving assessment tools to measure and build students’ problem-solving skills today! These skills will be invaluable to students now and in the future.

Ready to Get Started?

Learn more about cae’s suite of products and let’s get started measuring and teaching students important higher-order skills like problem solving..

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Problem Solving

How to Improve Problem Solving Skills

Last Updated: January 27, 2024 Fact Checked

This article was co-authored by Erin Conlon, PCC, JD . Erin Conlon is an Executive Life Coach, the Founder of Erin Conlon Coaching, and the host of the podcast "This is Not Advice." She specializes in aiding leaders and executives to thrive in their career and personal lives. In addition to her private coaching practice, she teaches and trains coaches and develops and revises training materials to be more diverse, equitable, and inclusive. She holds a BA in Communications and History and a JD from The University of Michigan. Erin is a Professional Certified Coach with The International Coaching Federation. There are 13 references cited in this article, which can be found at the bottom of the page. This article has been fact-checked, ensuring the accuracy of any cited facts and confirming the authority of its sources. This article has been viewed 234,828 times.

The ability to solve problems applies to more than just mathematics homework. Analytical thinking and problem-solving skills are a part of many jobs, ranging from accounting and computer programming to detective work and even creative occupations like art, acting, and writing. While individual problems vary, there are certain general approaches to problem-solving like the one first proposed by mathematician George Polya in 1945. [1] X Research source By following his principles of understanding the problem, devising a plan, carrying out the plan, and looking back, you can improve your problem-solving and tackle any issue systematically.

Define the problem clearly.

This is an outwardly simple but vital step.

Try to formulate questions. Say that as a student you have very little money and want to find an effective solution. What is at issue? Is it one of income – are you not making enough money? Is it one of over-spending? Or perhaps you have run into unexpected expenses or your financial situation has changed?

State your objective.

This is another means to reach the nature of the problem.

Say that your problem is still money. What is your goal? Perhaps you never have enough to go out on the weekend and have fun at the movies or a club. You decide that your goal is to have more spending cash. Good! With a clear goal, you have better defined the problem.

Gather information systematically.

Gathering facts helps you get a clear picture of your problem and goal.

To solve your money shortage, for example, you would want to get as detailed a picture of your financial situation as possible. Collect data through your latest bank statements and to talk to a bank teller. Track your earnings and spending habits in a notebook, and then create a spreadsheet or chart to show your income alongside your expenditures.

Analyze information.

Looking for links and relationships in your data can help you better understand your situation.

Say you have now collected all your bank statements. Look at them. When, how, and from where is your money coming? Where, when, and how are you spending it? What is the overall pattern of your finances? Do you have a net surplus or deficit? Are there any unexplained items?

Generate possible solutions.

This is a great time to consider all of your options.

Your problem is a lack of money. Your goal is to have more spending cash. What are your options? Without evaluating them, come up with possible options. Perhaps you can acquire more money by getting a part-time job or by taking out a student loan. On the other hand, you might try to save by cutting your spending or by lowering other costs.
Divide and conquer. Break the problem into smaller problems and brainstorm solutions for them separately, one by one.
Use analogies and similarities. Try to find a resemblance with a previously solved or common problem. If you can find commonalities between your situation and one you've dealt with before, you may be able to adapt some of the solutions for use now.

Evaluate the solutions and choose.

A thorough analysis helps you make the best possible choice.

How can you raise money? Look at expenditures – you aren’t spending much outside of basic needs like tuition, food, and housing. Can you cut costs in other ways like finding a roommate to split rent? Can you afford to take a student loan just to have fun on the weekend? Can you spare time from your studies to work part-time?
Each solution will produce its own set of circumstances that need evaluation. Run projections. Your money problem will require you to draw up budgets. But it will also take personal consideration. For example, can you cut back on basic things like food or housing? Are you willing to prioritize money over school or to take on debt?

Implement a solution.

This gives you a chance to see how effective your solution really is.

You decide to cut costs, because you were unwilling to take on debt, to divert time away from school, or to live with a roommate. You draw up a detailed budget, cutting a few dollars here and there, and commit to a month-long trial.

Review and evaluate the outcome.

Ask yourself if the solution is working, or if it needs to be adjusted.

The results of your trial are mixed. On one hand, you have saved enough during the month for fun weekend activities. But there are new problems. You find that you must choose between spending cash and buying basics like food. You also need a new pair of shoes but can’t afford it, according to your budget. You may need to a different solution.

Adjust if necessary.

It’s okay if your first solution doesn’t work out.

After a month, you decide to abandon your first budget and to look for part-time work. You find a work-study job on campus. Making a new budget, you now have extra money without taking too much time away from your studies. You may have an effective solution.

Do regular mental exercises.

Like a muscle in your body, you will need to work on problem solving regularly.

Word games work great. In a game like “Split Words,” for example, you have to match word fragments to form words under a given theme like “philosophy.” In the game, “Tower of Babel,” you will need to memorize and then match words in a foreign language to the proper picture.
Mathematical games will also put your problem solving to the test. Whether it be number or word problems, you will have to activate the parts of your brain that analyze information. For instance: “James is half as old now as he will be when he is 60 years older than he was six years before he was half as old as he is now. How old will James be when his age is twice what it was 10 years after he was half his current age?”

Play video games.

New research shows that playing video games can improve parts of your thinking.

Play something that will force you to think strategically or analytically. Try a puzzle game like Tetris. Or, perhaps you would rather prefer a role-playing or strategy game. In that case, something like “Civilization” or “Sim-City” might suit you better.

Take up a hobby.

A hobby is another way that you can continue to improve your problem solving skills.

Web design, software programming, jigsaw puzzles, Sudoku, and chess are also hobbies that will force you to think strategically and systematically. Any of these will help you improve your overall problem solving.

Expert Q&A

↑ https://math.berkeley.edu/~gmelvin/polya.pdf
↑ https://www.healthywa.wa.gov.au/Articles/N_R/Problem-solving
↑ https://asq.org/quality-resources/problem-solving
↑ https://ctb.ku.edu/en/table-of-contents/evaluate/evaluate-community-interventions/collect-analyze-data/main
↑ https://www.mindtools.com/pages/article/newCT_96.htm
↑ https://www.skillsyouneed.com/ips/problem-solving.html
↑ Erin Conlon, PCC, JD. Executive Life Coach. Expert Interview. 31 August 2021.
↑ https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5930973/
↑ https://www.theguardian.com/lifeandstyle/2018/oct/13/mental-exercises-to-keep-your-brain-sharp
↑ https://www.apa.org/monitor/2014/02/video-game
↑ https://www.nature.com/articles/d41586-018-05449-7

About This Article

To improve your problem-solving skills, start by clearly defining the problem and your objective or goal. Next, gather as much information as you can about the problem and organize the data by rewording, condensing, or summarizing it. Then, analyze the information you've gathered, looking for important links, patterns, and relationships in the data. Finally, brainstorm possible solutions, evaluate the solutions, and choose one to implement. For tips on implementing solutions successfully, read on! Did this summary help you? Yes No

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3 Ways to Improve Your Students’ Problem-Solving Skills

Teaching problem solving doesn’t have to be something you dread. Students can and should enjoy feeling challenged and having to persevere through a difficult task. In this article, we lay out three ways we have found success for incorporating problem-solving into our teaching. Learn more through an on-demand webinar .

Problem-Solving Challenges

Have you ever wondered why students often struggle with problem solving in math? Well, problem solving is… challenging! Additionally, if problem solving is difficult, then teaching how to solve problems is even more demanding. There are some common reasons we believe teachers struggle to support students in developing problem-solving skills. They are:

Problem-solving is often taught in conjunction with mnemonics and memorized procedures that are not predictable and that take focus away from the literacy and mathematics of the task
Problems chosen are often too routine or familiar for students
Problem structures do not vary enough between tasks chosen
Instruction seldom includes reflecting and writing about mathematical practices/processes used to problem solve

Even more, word problems...

have lots of… you guessed it: words! This can be very daunting for all students, especially for linguistic learners who are still mastering the language.

Improving Student Problem-Solving

Based on our experiences and successes, there are strategic ways incorporating problem- solving into our teaching. Here are three ways that you can support students by incorporating problem solving into your teaching.

Way 1: Use high cognitive demand tasks.

It’s called problem-solving for a reason! There must be an actual problem to solve! After all, a problem isn’t a problem if students already know how to solve it!

Thus, it’s very important to use high cognitive demand tasks in your teaching of problem- solving. These types of tasks engage students in mathematical thinking. They also require students to experience some sort of productive struggle. High cognitive demand tasks may have multiple solutions, or solution paths that are not obvious. They may also have constraints that restrict the number of solutions or strategies.

Teachers’ expectations for student success set the benchmark for students to achieve. When that benchmark is low, student achievement is low. When that benchmark is high, students have an opportunity to rise to that higher level. Providing students with types of tasks that they have not encountered before, and challenging students to make sense of a question, places them at the center of the problem-solving process. Ultimately, then, students are required to think mathematically as opposed to memorizing and regurgitating a set of procedures.

Take a look at the following third grade task:

This task is representative of a high cognitive demand task. Here’s why:

The task has multiple solutions to each question.
There are various ways to go about solving the problem.
The task is not about applying a memorized procedure such as how to find the area or perimeter of a rectangle, despite the provided labeled wooden board with dimensions.
To answer the questions, students are required to use complex thinking as well as a deep understanding of how the concept of fractions connects to geometry

Teaching problem-solving is much more successful when students are provided tasks that require them to think critically.

Way 2: Offer language support, as needed.

Problems can often be wordy and may muddy the water between whether we are assessing reading skills or mathematics. To ensure the focus is on mathematics, we suggest considering which vocabulary words or grammatical structures might present difficulties. This allows teachers to be better prepared to support challenges that students may encounter.

For example, in the Closet Task problem, the word ‘whole’ when read aloud sounds like ‘hole’. The understanding of the word ‘whole’ is vital to the problem—students must comprehend that the whole board represents the denominator, the entire thing. If students are visualizing a wooden board with holes, they will never have the opportunity to show their understanding of the mathematics content.

Therefore, we suggest previewing important vocabulary before students solve a problem in order to ensure understanding of the task at hand. More specifically, we recommend teachers define appropriate Tier 2 and/or Tier 3 vocabulary words, as needed, for the students they serve.

In addition to pre-teaching important vocabulary, we also suggest calling out challenging grammatical structures. These include phrases with modal phrases like “You have to multiply the length by the width to find the area of a rectangle” or conditional phrases such as, “If you multiply any number by zero, then the product will always be zero.”

Way 3: Provide opportunities for students to engage in structured discourse.

Problem-solving is often thought of as an isolated topic in math classes. Some might even imagine it to look like students working independently. When presented with a problem in the real world, we often seek others’ help. Problem-solving in math class should mirror the real world. Collaboration is a vital skill that can provide students with the support they need in developing their own abilities to share their thinking and in listening to one another.

In order to collaborate successfully, students need to be explicitly taught how to have a math dialogue. This is why we suggest teachers provide students with specific sentence frames that allow for students to structure their discourse so their conversations are meaningful. Structured discourse also supports students in having equal airtime. Additionally, it ensures that students are listening to understand, not listening to respond.

For example, take a look at this protocol that features structured sentence frames to be used after students have solved a task independently:

Norris, K. & Kreisberg, H. (2021). Let's Talk Math. TCM: Huntington Beach, CA.

Students know exactly how to engage in the conversation. Each student is held accountable for listening and understanding by being asked to rephrase what their partner said. Students then analyze their own strategies and discuss their problem-solving process. Students' learning deepens when they articulate their own understanding as they progress through a meaningful task, as well as when they draw conclusions based on their work.

Problem-solving skills may be enhanced when students are able to communicate effectively about their problem solving process and the mathematical strategies they used.

Successful Problem-Solving

While teaching problem-solving is no easy feat, it doesn’t have to be something to dread! Students can be successful problem solvers when they

problem solve using demanding tasks that cause them to critically think
collaborate to break down language barriers that often prevent them from accessing the task
use structured protocols that promote meaningful mathematical discourse
reflect on their problem solving process both orally and in writing

Imagine this:

This scenario illustrates what a classroom can look like where students are active participants in the problem-solving process. In this classroom, students use structured protocols that facilitate them in understanding the task and identifying important information. Students gain self- confidence as they share their thinking and are active listeners in their discussions. They think mathematically, communicate their understandings orally and in writing, and identify connections among mathematical content and strategies.

With the three strategies included in this article, teachers can overcome the challenges of teaching problem-solving and support students in becoming successful, independent problem-solvers. By using high cognitive demand tasks, offering language support, and providing opportunities for students to engage in structured discourse, teachers can empower students to persevere as problem solvers.

Let's Talk Math: Your Guide to Successful Problem-Solving Instruction

Deepen your understanding of teaching problem solving effectively with the authors of Let’s Talk Math , a researched-based, standards-aligned curricular resource for grades K–5. In this webinar, participants will learn:

three Steps for Problem-Solving Success which puts students at the center of mathematical learning
how to support learners in becoming more confident mathematical thinkers
how Let’s Talk Math enhances both students’ mathematical content knowledge and problem-solving skills, as well as oral and written communication skills

Categories:

Author bio:, dr. hilary kreisberg.

Dr. Hilary Kreisberg is the director of the Center for Mathematics Achievement and an assistant professor of mathematics education at Lesley University. Dr. Kreisberg was previously a K–5 math coach and an elementary educator and has a Doctor of Education degree in Educational Leadership and Curriculum Development, a Master of Arts degree in Teaching and Special Education, and a Bachelor of Arts degree in Mathematics. An award-winning author, Dr. Kreisberg has been featured in multiple...

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How to improve your problem solving skills and build effective problem solving strategies

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What is a problem solving process?

What are the problem solving steps I need to follow?

Problem solving strategies

What skills do i need to be an effective problem solver, how can i improve my problem solving skills.

Solving problems is like baking a cake. You can go straight into the kitchen without a recipe or the right ingredients and do your best, but the end result is unlikely to be very tasty!

Using a process to bake a cake allows you to use the best ingredients without waste, collect the right tools, account for allergies, decide whether it is a birthday or wedding cake, and then bake efficiently and on time. The result is a better cake that is fit for purpose, tastes better and has created less mess in the kitchen. Also, it should have chocolate sprinkles. Having a step by step process to solve organizational problems allows you to go through each stage methodically and ensure you are trying to solve the right problems and select the most appropriate, effective solutions.

What are the problem solving steps I need to follow?

All problem solving processes go through a number of steps in order to move from identifying a problem to resolving it.

Depending on your problem solving model and who you ask, there can be anything between four and nine problem solving steps you should follow in order to find the right solution. Whatever framework you and your group use, there are some key items that should be addressed in order to have an effective process.

We’ve looked at problem solving processes from sources such as the American Society for Quality and their four step approach , and Mediate ‘s six step process. By reflecting on those and our own problem solving processes, we’ve come up with a sequence of seven problem solving steps we feel best covers everything you need in order to effectively solve problems.

1. Problem identification

The first stage of any problem solving process is to identify the problem or problems you might want to solve. Effective problem solving strategies always begin by allowing a group scope to articulate what they believe the problem to be and then coming to some consensus over which problem they approach first. Problem solving activities used at this stage often have a focus on creating frank, open discussion so that potential problems can be brought to the surface.

2. Problem analysis

Though this step is not a million miles from problem identification, problem analysis deserves to be considered separately. It can often be an overlooked part of the process and is instrumental when it comes to developing effective solutions.

The process of problem analysis means ensuring that the problem you are seeking to solve is the right problem . As part of this stage, you may look deeper and try to find the root cause of a specific problem at a team or organizational level.

Remember that problem solving strategies should not only be focused on putting out fires in the short term but developing long term solutions that deal with the root cause of organizational challenges.

Whatever your approach, analyzing a problem is crucial in being able to select an appropriate solution and the problem solving skills deployed in this stage are beneficial for the rest of the process and ensuring the solutions you create are fit for purpose.

3. Solution generation

Once your group has nailed down the particulars of the problem you wish to solve, you want to encourage a free flow of ideas connecting to solving that problem. This can take the form of problem solving games that encourage creative thinking or problem solving activities designed to produce working prototypes of possible solutions.

The key to ensuring the success of this stage of the problem solving process is to encourage quick, creative thinking and create an open space where all ideas are considered. The best solutions can come from unlikely places and by using problem solving techniques that celebrate invention, you might come up with solution gold.

4. Solution development

No solution is likely to be perfect right out of the gate. It’s important to discuss and develop the solutions your group has come up with over the course of following the previous problem solving steps in order to arrive at the best possible solution. Problem solving games used in this stage involve lots of critical thinking, measuring potential effort and impact, and looking at possible solutions analytically.

During this stage, you will often ask your team to iterate and improve upon your frontrunning solutions and develop them further. Remember that problem solving strategies always benefit from a multitude of voices and opinions, and not to let ego get involved when it comes to choosing which solutions to develop and take further.

Finding the best solution is the goal of all problem solving workshops and here is the place to ensure that your solution is well thought out, sufficiently robust and fit for purpose.

5. Decision making

Nearly there! Once your group has reached consensus and selected a solution that applies to the problem at hand you have some decisions to make. You will want to work on allocating ownership of the project, figure out who will do what, how the success of the solution will be measured and decide the next course of action.

The decision making stage is a part of the problem solving process that can get missed or taken as for granted. Fail to properly allocate roles and plan out how a solution will actually be implemented and it less likely to be successful in solving the problem.

Have clear accountabilities, actions, timeframes, and follow-ups. Make these decisions and set clear next-steps in the problem solving workshop so that everyone is aligned and you can move forward effectively as a group.

Ensuring that you plan for the roll-out of a solution is one of the most important problem solving steps. Without adequate planning or oversight, it can prove impossible to measure success or iterate further if the problem was not solved.

6. Solution implementation

This is what we were waiting for! All problem solving strategies have the end goal of implementing a solution and solving a problem in mind.

Remember that in order for any solution to be successful, you need to help your group through all of the previous problem solving steps thoughtfully. Only then can you ensure that you are solving the right problem but also that you have developed the correct solution and can then successfully implement and measure the impact of that solution.

Project management and communication skills are key here – your solution may need to adjust when out in the wild or you might discover new challenges along the way.

7. Solution evaluation

So you and your team developed a great solution to a problem and have a gut feeling its been solved. Work done, right? Wrong. All problem solving strategies benefit from evaluation, consideration, and feedback. You might find that the solution does not work for everyone, might create new problems, or is potentially so successful that you will want to roll it out to larger teams or as part of other initiatives.

None of that is possible without taking the time to evaluate the success of the solution you developed in your problem solving model and adjust if necessary.

Remember that the problem solving process is often iterative and it can be common to not solve complex issues on the first try. Even when this is the case, you and your team will have generated learning that will be important for future problem solving workshops or in other parts of the organization.

It’s worth underlining how important record keeping is throughout the problem solving process. If a solution didn’t work, you need to have the data and records to see why that was the case. If you go back to the drawing board, notes from the previous workshop can help save time. Data and insight is invaluable at every stage of the problem solving process and this one is no different.

Problem solving workshops made easy

Problem solving strategies are methods of approaching and facilitating the process of problem-solving with a set of techniques , actions, and processes. Different strategies are more effective if you are trying to solve broad problems such as achieving higher growth versus more focused problems like, how do we improve our customer onboarding process?

Broadly, the problem solving steps outlined above should be included in any problem solving strategy though choosing where to focus your time and what approaches should be taken is where they begin to differ. You might find that some strategies ask for the problem identification to be done prior to the session or that everything happens in the course of a one day workshop.

The key similarity is that all good problem solving strategies are structured and designed. Four hours of open discussion is never going to be as productive as a four-hour workshop designed to lead a group through a problem solving process.

Good problem solving strategies are tailored to the team, organization and problem you will be attempting to solve. Here are some example problem solving strategies you can learn from or use to get started.

Use a workshop to lead a team through a group process

Often, the first step to solving problems or organizational challenges is bringing a group together effectively. Most teams have the tools, knowledge, and expertise necessary to solve their challenges – they just need some guidance in how to use leverage those skills and a structure and format that allows people to focus their energies.

Facilitated workshops are one of the most effective ways of solving problems of any scale. By designing and planning your workshop carefully, you can tailor the approach and scope to best fit the needs of your team and organization.

Problem solving workshop

Creating a bespoke, tailored process
Tackling problems of any size
Building in-house workshop ability and encouraging their use

Workshops are an effective strategy for solving problems. By using tried and test facilitation techniques and methods, you can design and deliver a workshop that is perfectly suited to the unique variables of your organization. You may only have the capacity for a half-day workshop and so need a problem solving process to match.

By using our session planner tool and importing methods from our library of 700+ facilitation techniques, you can create the right problem solving workshop for your team. It might be that you want to encourage creative thinking or look at things from a new angle to unblock your groups approach to problem solving. By tailoring your workshop design to the purpose, you can help ensure great results.

One of the main benefits of a workshop is the structured approach to problem solving. Not only does this mean that the workshop itself will be successful, but many of the methods and techniques will help your team improve their working processes outside of the workshop.

We believe that workshops are one of the best tools you can use to improve the way your team works together. Start with a problem solving workshop and then see what team building, culture or design workshops can do for your organization!

Run a design sprint

Great for:

aligning large, multi-discipline teams
quickly designing and testing solutions
tackling large, complex organizational challenges and breaking them down into smaller tasks

By using design thinking principles and methods, a design sprint is a great way of identifying, prioritizing and prototyping solutions to long term challenges that can help solve major organizational problems with quick action and measurable results.

Some familiarity with design thinking is useful, though not integral, and this strategy can really help a team align if there is some discussion around which problems should be approached first.

The stage-based structure of the design sprint is also very useful for teams new to design thinking. The inspiration phase, where you look to competitors that have solved your problem, and the rapid prototyping and testing phases are great for introducing new concepts that will benefit a team in all their future work.

It can be common for teams to look inward for solutions and so looking to the market for solutions you can iterate on can be very productive. Instilling an agile prototyping and testing mindset can also be great when helping teams move forwards – generating and testing solutions quickly can help save time in the long run and is also pretty exciting!

Break problems down into smaller issues

Organizational challenges and problems are often complicated and large scale in nature. Sometimes, trying to resolve such an issue in one swoop is simply unachievable or overwhelming. Try breaking down such problems into smaller issues that you can work on step by step. You may not be able to solve the problem of churning customers off the bat, but you can work with your team to identify smaller effort but high impact elements and work on those first.

This problem solving strategy can help a team generate momentum, prioritize and get some easy wins. It’s also a great strategy to employ with teams who are just beginning to learn how to approach the problem solving process. If you want some insight into a way to employ this strategy, we recommend looking at our design sprint template below!

Use guiding frameworks or try new methodologies

Some problems are best solved by introducing a major shift in perspective or by using new methodologies that encourage your team to think differently.

Props and tools such as Methodkit , which uses a card-based toolkit for facilitation, or Lego Serious Play can be great ways to engage your team and find an inclusive, democratic problem solving strategy. Remember that play and creativity are great tools for achieving change and whatever the challenge, engaging your participants can be very effective where other strategies may have failed.

LEGO Serious Play

Improving core problem solving skills
Thinking outside of the box
Encouraging creative solutions

LEGO Serious Play is a problem solving methodology designed to get participants thinking differently by using 3D models and kinesthetic learning styles. By physically building LEGO models based on questions and exercises, participants are encouraged to think outside of the box and create their own responses.

Collaborate LEGO Serious Play exercises are also used to encourage communication and build problem solving skills in a group. By using this problem solving process, you can often help different kinds of learners and personality types contribute and unblock organizational problems with creative thinking.

Problem solving strategies like LEGO Serious Play are super effective at helping a team solve more skills-based problems such as communication between teams or a lack of creative thinking. Some problems are not suited to LEGO Serious Play and require a different problem solving strategy.

Card Decks and Method Kits

New facilitators or non-facilitators
Approaching difficult subjects with a simple, creative framework
Engaging those with varied learning styles

Card decks and method kids are great tools for those new to facilitation or for whom facilitation is not the primary role. Card decks such as the emotional culture deck can be used for complete workshops and in many cases, can be used right out of the box. Methodkit has a variety of kits designed for scenarios ranging from personal development through to personas and global challenges so you can find the right deck for your particular needs.

Having an easy to use framework that encourages creativity or a new approach can take some of the friction or planning difficulties out of the workshop process and energize a team in any setting. Simplicity is the key with these methods. By ensuring everyone on your team can get involved and engage with the process as quickly as possible can really contribute to the success of your problem solving strategy.

Source external advice

Looking to peers, experts and external facilitators can be a great way of approaching the problem solving process. Your team may not have the necessary expertise, insights of experience to tackle some issues, or you might simply benefit from a fresh perspective. Some problems may require bringing together an entire team, and coaching managers or team members individually might be the right approach. Remember that not all problems are best resolved in the same manner.

If you’re a solo entrepreneur, peer groups, coaches and mentors can also be invaluable at not only solving specific business problems, but in providing a support network for resolving future challenges. One great approach is to join a Mastermind Group and link up with like-minded individuals and all grow together. Remember that however you approach the sourcing of external advice, do so thoughtfully, respectfully and honestly. Reciprocate where you can and prepare to be surprised by just how kind and helpful your peers can be!

Mastermind Group

Solo entrepreneurs or small teams with low capacity
Peer learning and gaining outside expertise
Getting multiple external points of view quickly

Problem solving in large organizations with lots of skilled team members is one thing, but how about if you work for yourself or in a very small team without the capacity to get the most from a design sprint or LEGO Serious Play session?

A mastermind group – sometimes known as a peer advisory board – is where a group of people come together to support one another in their own goals, challenges, and businesses. Each participant comes to the group with their own purpose and the other members of the group will help them create solutions, brainstorm ideas, and support one another.

Mastermind groups are very effective in creating an energized, supportive atmosphere that can deliver meaningful results. Learning from peers from outside of your organization or industry can really help unlock new ways of thinking and drive growth. Access to the experience and skills of your peers can be invaluable in helping fill the gaps in your own ability, particularly in young companies.

A mastermind group is a great solution for solo entrepreneurs, small teams, or for organizations that feel that external expertise or fresh perspectives will be beneficial for them. It is worth noting that Mastermind groups are often only as good as the participants and what they can bring to the group. Participants need to be committed, engaged and understand how to work in this context.

Coaching and mentoring

Focused learning and development
Filling skills gaps
Working on a range of challenges over time

Receiving advice from a business coach or building a mentor/mentee relationship can be an effective way of resolving certain challenges. The one-to-one format of most coaching and mentor relationships can really help solve the challenges those individuals are having and benefit the organization as a result.

A great mentor can be invaluable when it comes to spotting potential problems before they arise and coming to understand a mentee very well has a host of other business benefits. You might run an internal mentorship program to help develop your team’s problem solving skills and strategies or as part of a large learning and development program. External coaches can also be an important part of your problem solving strategy, filling skills gaps for your management team or helping with specific business issues.

Now we’ve explored the problem solving process and the steps you will want to go through in order to have an effective session, let’s look at the skills you and your team need to be more effective problem solvers.

Problem solving skills are highly sought after, whatever industry or team you work in. Organizations are keen to employ people who are able to approach problems thoughtfully and find strong, realistic solutions. Whether you are a facilitator , a team leader or a developer, being an effective problem solver is a skill you’ll want to develop.

Problem solving skills form a whole suite of techniques and approaches that an individual uses to not only identify problems but to discuss them productively before then developing appropriate solutions.

Here are some of the most important problem solving skills everyone from executives to junior staff members should learn. We’ve also included an activity or exercise from the SessionLab library that can help you and your team develop that skill.

If you’re running a workshop or training session to try and improve problem solving skills in your team, try using these methods to supercharge your process!

Active listening

Active listening is one of the most important skills anyone who works with people can possess. In short, active listening is a technique used to not only better understand what is being said by an individual, but also to be more aware of the underlying message the speaker is trying to convey. When it comes to problem solving, active listening is integral for understanding the position of every participant and to clarify the challenges, ideas and solutions they bring to the table.

Some active listening skills include:

Paying complete attention to the speaker.
Removing distractions.
Avoid interruption.
Taking the time to fully understand before preparing a rebuttal.
Responding respectfully and appropriately.
Demonstrate attentiveness and positivity with an open posture, making eye contact with the speaker, smiling and nodding if appropriate. Show that you are listening and encourage them to continue.
Be aware of and respectful of feelings. Judge the situation and respond appropriately. You can disagree without being disrespectful.
Observe body language.
Paraphrase what was said in your own words, either mentally or verbally.
Remain neutral.
Reflect and take a moment before responding.
Ask deeper questions based on what is said and clarify points where necessary.

Active Listening #hyperisland #skills #active listening #remote-friendly This activity supports participants to reflect on a question and generate their own solutions using simple principles of active listening and peer coaching. It’s an excellent introduction to active listening but can also be used with groups that are already familiar with it. Participants work in groups of three and take turns being: “the subject”, the listener, and the observer.

Analytical skills

All problem solving models require strong analytical skills, particularly during the beginning of the process and when it comes to analyzing how solutions have performed.

Analytical skills are primarily focused on performing an effective analysis by collecting, studying and parsing data related to a problem or opportunity.

It often involves spotting patterns, being able to see things from different perspectives and using observable facts and data to make suggestions or produce insight.

Analytical skills are also important at every stage of the problem solving process and by having these skills, you can ensure that any ideas or solutions you create or backed up analytically and have been sufficiently thought out.

Nine Whys #innovation #issue analysis #liberating structures With breathtaking simplicity, you can rapidly clarify for individuals and a group what is essentially important in their work. You can quickly reveal when a compelling purpose is missing in a gathering and avoid moving forward without clarity. When a group discovers an unambiguous shared purpose, more freedom and more responsibility are unleashed. You have laid the foundation for spreading and scaling innovations with fidelity.

Collaboration

Trying to solve problems on your own is difficult. Being able to collaborate effectively, with a free exchange of ideas, to delegate and be a productive member of a team is hugely important to all problem solving strategies.

Remember that whatever your role, collaboration is integral, and in a problem solving process, you are all working together to find the best solution for everyone.

Marshmallow challenge with debriefing #teamwork #team #leadership #collaboration In eighteen minutes, teams must build the tallest free-standing structure out of 20 sticks of spaghetti, one yard of tape, one yard of string, and one marshmallow. The marshmallow needs to be on top. The Marshmallow Challenge was developed by Tom Wujec, who has done the activity with hundreds of groups around the world. Visit the Marshmallow Challenge website for more information. This version has an extra debriefing question added with sample questions focusing on roles within the team.

Communication

Being an effective communicator means being empathetic, clear and succinct, asking the right questions, and demonstrating active listening skills throughout any discussion or meeting.

In a problem solving setting, you need to communicate well in order to progress through each stage of the process effectively. As a team leader, it may also fall to you to facilitate communication between parties who may not see eye to eye. Effective communication also means helping others to express themselves and be heard in a group.

Bus Trip #feedback #communication #appreciation #closing #thiagi #team This is one of my favourite feedback games. I use Bus Trip at the end of a training session or a meeting, and I use it all the time. The game creates a massive amount of energy with lots of smiles, laughs, and sometimes even a teardrop or two.

Creative problem solving skills can be some of the best tools in your arsenal. Thinking creatively, being able to generate lots of ideas and come up with out of the box solutions is useful at every step of the process.

The kinds of problems you will likely discuss in a problem solving workshop are often difficult to solve, and by approaching things in a fresh, creative manner, you can often create more innovative solutions.

Having practical creative skills is also a boon when it comes to problem solving. If you can help create quality design sketches and prototypes in record time, it can help bring a team to alignment more quickly or provide a base for further iteration.

The paper clip method #sharing #creativity #warm up #idea generation #brainstorming The power of brainstorming. A training for project leaders, creativity training, and to catalyse getting new solutions.

Critical thinking

Critical thinking is one of the fundamental problem solving skills you’ll want to develop when working on developing solutions. Critical thinking is the ability to analyze, rationalize and evaluate while being aware of personal bias, outlying factors and remaining open-minded.

Defining and analyzing problems without deploying critical thinking skills can mean you and your team go down the wrong path. Developing solutions to complex issues requires critical thinking too – ensuring your team considers all possibilities and rationally evaluating them.

Agreement-Certainty Matrix #issue analysis #liberating structures #problem solving You can help individuals or groups avoid the frequent mistake of trying to solve a problem with methods that are not adapted to the nature of their challenge. The combination of two questions makes it possible to easily sort challenges into four categories: simple, complicated, complex , and chaotic . A problem is simple when it can be solved reliably with practices that are easy to duplicate. It is complicated when experts are required to devise a sophisticated solution that will yield the desired results predictably. A problem is complex when there are several valid ways to proceed but outcomes are not predictable in detail. Chaotic is when the context is too turbulent to identify a path forward. A loose analogy may be used to describe these differences: simple is like following a recipe, complicated like sending a rocket to the moon, complex like raising a child, and chaotic is like the game “Pin the Tail on the Donkey.” The Liberating Structures Matching Matrix in Chapter 5 can be used as the first step to clarify the nature of a challenge and avoid the mismatches between problems and solutions that are frequently at the root of chronic, recurring problems.

Data analysis

Though it shares lots of space with general analytical skills, data analysis skills are something you want to cultivate in their own right in order to be an effective problem solver.

Being good at data analysis doesn’t just mean being able to find insights from data, but also selecting the appropriate data for a given issue, interpreting it effectively and knowing how to model and present that data. Depending on the problem at hand, it might also include a working knowledge of specific data analysis tools and procedures.

Having a solid grasp of data analysis techniques is useful if you’re leading a problem solving workshop but if you’re not an expert, don’t worry. Bring people into the group who has this skill set and help your team be more effective as a result.

Decision making

All problems need a solution and all solutions require that someone make the decision to implement them. Without strong decision making skills, teams can become bogged down in discussion and less effective as a result.

Making decisions is a key part of the problem solving process. It’s important to remember that decision making is not restricted to the leadership team. Every staff member makes decisions every day and developing these skills ensures that your team is able to solve problems at any scale. Remember that making decisions does not mean leaping to the first solution but weighing up the options and coming to an informed, well thought out solution to any given problem that works for the whole team.

Lightning Decision Jam (LDJ) #action #decision making #problem solving #issue analysis #innovation #design #remote-friendly The problem with anything that requires creative thinking is that it’s easy to get lost—lose focus and fall into the trap of having useless, open-ended, unstructured discussions. Here’s the most effective solution I’ve found: Replace all open, unstructured discussion with a clear process. What to use this exercise for: Anything which requires a group of people to make decisions, solve problems or discuss challenges. It’s always good to frame an LDJ session with a broad topic, here are some examples: The conversion flow of our checkout Our internal design process How we organise events Keeping up with our competition Improving sales flow

Dependability

Most complex organizational problems require multiple people to be involved in delivering the solution. Ensuring that the team and organization can depend on you to take the necessary actions and communicate where necessary is key to ensuring problems are solved effectively.

Being dependable also means working to deadlines and to brief. It is often a matter of creating trust in a team so that everyone can depend on one another to complete the agreed actions in the agreed time frame so that the team can move forward together. Being undependable can create problems of friction and can limit the effectiveness of your solutions so be sure to bear this in mind throughout a project.

Team Purpose & Culture #team #hyperisland #culture #remote-friendly This is an essential process designed to help teams define their purpose (why they exist) and their culture (how they work together to achieve that purpose). Defining these two things will help any team to be more focused and aligned. With support of tangible examples from other companies, the team members work as individuals and a group to codify the way they work together. The goal is a visual manifestation of both the purpose and culture that can be put up in the team’s work space.

Emotional intelligence

Emotional intelligence is an important skill for any successful team member, whether communicating internally or with clients or users. In the problem solving process, emotional intelligence means being attuned to how people are feeling and thinking, communicating effectively and being self-aware of what you bring to a room.

There are often differences of opinion when working through problem solving processes, and it can be easy to let things become impassioned or combative. Developing your emotional intelligence means being empathetic to your colleagues and managing your own emotions throughout the problem and solution process. Be kind, be thoughtful and put your points across care and attention.

Being emotionally intelligent is a skill for life and by deploying it at work, you can not only work efficiently but empathetically. Check out the emotional culture workshop template for more!

Facilitation

As we’ve clarified in our facilitation skills post, facilitation is the art of leading people through processes towards agreed-upon objectives in a manner that encourages participation, ownership, and creativity by all those involved. While facilitation is a set of interrelated skills in itself, the broad definition of facilitation can be invaluable when it comes to problem solving. Leading a team through a problem solving process is made more effective if you improve and utilize facilitation skills – whether you’re a manager, team leader or external stakeholder.

The Six Thinking Hats #creative thinking #meeting facilitation #problem solving #issue resolution #idea generation #conflict resolution The Six Thinking Hats are used by individuals and groups to separate out conflicting styles of thinking. They enable and encourage a group of people to think constructively together in exploring and implementing change, rather than using argument to fight over who is right and who is wrong.

Flexibility

Being flexible is a vital skill when it comes to problem solving. This does not mean immediately bowing to pressure or changing your opinion quickly: instead, being flexible is all about seeing things from new perspectives, receiving new information and factoring it into your thought process.

Flexibility is also important when it comes to rolling out solutions. It might be that other organizational projects have greater priority or require the same resources as your chosen solution. Being flexible means understanding needs and challenges across the team and being open to shifting or arranging your own schedule as necessary. Again, this does not mean immediately making way for other projects. It’s about articulating your own needs, understanding the needs of others and being able to come to a meaningful compromise.

The Creativity Dice #creativity #problem solving #thiagi #issue analysis Too much linear thinking is hazardous to creative problem solving. To be creative, you should approach the problem (or the opportunity) from different points of view. You should leave a thought hanging in mid-air and move to another. This skipping around prevents premature closure and lets your brain incubate one line of thought while you consciously pursue another.

Working in any group can lead to unconscious elements of groupthink or situations in which you may not wish to be entirely honest. Disagreeing with the opinions of the executive team or wishing to save the feelings of a coworker can be tricky to navigate, but being honest is absolutely vital when to comes to developing effective solutions and ensuring your voice is heard.

Remember that being honest does not mean being brutally candid. You can deliver your honest feedback and opinions thoughtfully and without creating friction by using other skills such as emotional intelligence.

Explore your Values #hyperisland #skills #values #remote-friendly Your Values is an exercise for participants to explore what their most important values are. It’s done in an intuitive and rapid way to encourage participants to follow their intuitive feeling rather than over-thinking and finding the “correct” values. It is a good exercise to use to initiate reflection and dialogue around personal values.

Initiative

The problem solving process is multi-faceted and requires different approaches at certain points of the process. Taking initiative to bring problems to the attention of the team, collect data or lead the solution creating process is always valuable. You might even roadtest your own small scale solutions or brainstorm before a session. Taking initiative is particularly effective if you have good deal of knowledge in that area or have ownership of a particular project and want to get things kickstarted.

That said, be sure to remember to honor the process and work in service of the team. If you are asked to own one part of the problem solving process and you don’t complete that task because your initiative leads you to work on something else, that’s not an effective method of solving business challenges.

15% Solutions #action #liberating structures #remote-friendly You can reveal the actions, however small, that everyone can do immediately. At a minimum, these will create momentum, and that may make a BIG difference. 15% Solutions show that there is no reason to wait around, feel powerless, or fearful. They help people pick it up a level. They get individuals and the group to focus on what is within their discretion instead of what they cannot change. With a very simple question, you can flip the conversation to what can be done and find solutions to big problems that are often distributed widely in places not known in advance. Shifting a few grains of sand may trigger a landslide and change the whole landscape.

Impartiality

A particularly useful problem solving skill for product owners or managers is the ability to remain impartial throughout much of the process. In practice, this means treating all points of view and ideas brought forward in a meeting equally and ensuring that your own areas of interest or ownership are not favored over others.

There may be a stage in the process where a decision maker has to weigh the cost and ROI of possible solutions against the company roadmap though even then, ensuring that the decision made is based on merit and not personal opinion.

Empathy map #frame insights #create #design #issue analysis An empathy map is a tool to help a design team to empathize with the people they are designing for. You can make an empathy map for a group of people or for a persona. To be used after doing personas when more insights are needed.

Being a good leader means getting a team aligned, energized and focused around a common goal. In the problem solving process, strong leadership helps ensure that the process is efficient, that any conflicts are resolved and that a team is managed in the direction of success.

It’s common for managers or executives to assume this role in a problem solving workshop, though it’s important that the leader maintains impartiality and does not bulldoze the group in a particular direction. Remember that good leadership means working in service of the purpose and team and ensuring the workshop is a safe space for employees of any level to contribute. Take a look at our leadership games and activities post for more exercises and methods to help improve leadership in your organization.

Leadership Pizza #leadership #team #remote-friendly This leadership development activity offers a self-assessment framework for people to first identify what skills, attributes and attitudes they find important for effective leadership, and then assess their own development and initiate goal setting.

In the context of problem solving, mediation is important in keeping a team engaged, happy and free of conflict. When leading or facilitating a problem solving workshop, you are likely to run into differences of opinion. Depending on the nature of the problem, certain issues may be brought up that are emotive in nature.

Being an effective mediator means helping those people on either side of such a divide are heard, listen to one another and encouraged to find common ground and a resolution. Mediating skills are useful for leaders and managers in many situations and the problem solving process is no different.

Conflict Responses #hyperisland #team #issue resolution A workshop for a team to reflect on past conflicts, and use them to generate guidelines for effective conflict handling. The workshop uses the Thomas-Killman model of conflict responses to frame a reflective discussion. Use it to open up a discussion around conflict with a team.

Planning

Solving organizational problems is much more effective when following a process or problem solving model. Planning skills are vital in order to structure, deliver and follow-through on a problem solving workshop and ensure your solutions are intelligently deployed.

Planning skills include the ability to organize tasks and a team, plan and design the process and take into account any potential challenges. Taking the time to plan carefully can save time and frustration later in the process and is valuable for ensuring a team is positioned for success.

3 Action Steps #hyperisland #action #remote-friendly This is a small-scale strategic planning session that helps groups and individuals to take action toward a desired change. It is often used at the end of a workshop or programme. The group discusses and agrees on a vision, then creates some action steps that will lead them towards that vision. The scope of the challenge is also defined, through discussion of the helpful and harmful factors influencing the group.

Prioritization

As organisations grow, the scale and variation of problems they face multiplies. Your team or is likely to face numerous challenges in different areas and so having the skills to analyze and prioritize becomes very important, particularly for those in leadership roles.

A thorough problem solving process is likely to deliver multiple solutions and you may have several different problems you wish to solve simultaneously. Prioritization is the ability to measure the importance, value, and effectiveness of those possible solutions and choose which to enact and in what order. The process of prioritization is integral in ensuring the biggest challenges are addressed with the most impactful solutions.

Impact and Effort Matrix #gamestorming #decision making #action #remote-friendly In this decision-making exercise, possible actions are mapped based on two factors: effort required to implement and potential impact. Categorizing ideas along these lines is a useful technique in decision making, as it obliges contributors to balance and evaluate suggested actions before committing to them.

Project management

Some problem solving skills are utilized in a workshop or ideation phases, while others come in useful when it comes to decision making. Overseeing an entire problem solving process and ensuring its success requires strong project management skills.

While project management incorporates many of the other skills listed here, it is important to note the distinction of considering all of the factors of a project and managing them successfully. Being able to negotiate with stakeholders, manage tasks, time and people, consider costs and ROI, and tie everything together is massively helpful when going through the problem solving process.

Record keeping

Working out meaningful solutions to organizational challenges is only one part of the process. Thoughtfully documenting and keeping records of each problem solving step for future consultation is important in ensuring efficiency and meaningful change.

For example, some problems may be lower priority than others but can be revisited in the future. If the team has ideated on solutions and found some are not up to the task, record those so you can rule them out and avoiding repeating work. Keeping records of the process also helps you improve and refine your problem solving model next time around!

Personal Kanban #gamestorming #action #agile #project planning Personal Kanban is a tool for organizing your work to be more efficient and productive. It is based on agile methods and principles.

Research skills

Conducting research to support both the identification of problems and the development of appropriate solutions is important for an effective process. Knowing where to go to collect research, how to conduct research efficiently, and identifying pieces of research are relevant are all things a good researcher can do well.

In larger groups, not everyone has to demonstrate this ability in order for a problem solving workshop to be effective. That said, having people with research skills involved in the process, particularly if they have existing area knowledge, can help ensure the solutions that are developed with data that supports their intention. Remember that being able to deliver the results of research efficiently and in a way the team can easily understand is also important. The best data in the world is only as effective as how it is delivered and interpreted.

Customer experience map #ideation #concepts #research #design #issue analysis #remote-friendly Customer experience mapping is a method of documenting and visualizing the experience a customer has as they use the product or service. It also maps out their responses to their experiences. To be used when there is a solution (even in a conceptual stage) that can be analyzed.

Risk management

Managing risk is an often overlooked part of the problem solving process. Solutions are often developed with the intention of reducing exposure to risk or solving issues that create risk but sometimes, great solutions are more experimental in nature and as such, deploying them needs to be carefully considered.

Managing risk means acknowledging that there may be risks associated with more out of the box solutions or trying new things, but that this must be measured against the possible benefits and other organizational factors.

Be informed, get the right data and stakeholders in the room and you can appropriately factor risk into your decision making process.

Decisions, Decisions… #communication #decision making #thiagi #action #issue analysis When it comes to decision-making, why are some of us more prone to take risks while others are risk-averse? One explanation might be the way the decision and options were presented. This exercise, based on Kahneman and Tversky’s classic study , illustrates how the framing effect influences our judgement and our ability to make decisions . The participants are divided into two groups. Both groups are presented with the same problem and two alternative programs for solving them. The two programs both have the same consequences but are presented differently. The debriefing discussion examines how the framing of the program impacted the participant’s decision.

Team-building

No single person is as good at problem solving as a team. Building an effective team and helping them come together around a common purpose is one of the most important problem solving skills, doubly so for leaders. By bringing a team together and helping them work efficiently, you pave the way for team ownership of a problem and the development of effective solutions.

In a problem solving workshop, it can be tempting to jump right into the deep end, though taking the time to break the ice, energize the team and align them with a game or exercise will pay off over the course of the day.

Remember that you will likely go through the problem solving process multiple times over an organization’s lifespan and building a strong team culture will make future problem solving more effective. It’s also great to work with people you know, trust and have fun with. Working on team building in and out of the problem solving process is a hallmark of successful teams that can work together to solve business problems.

9 Dimensions Team Building Activity #ice breaker #teambuilding #team #remote-friendly 9 Dimensions is a powerful activity designed to build relationships and trust among team members. There are 2 variations of this icebreaker. The first version is for teams who want to get to know each other better. The second version is for teams who want to explore how they are working together as a team.

Time management

The problem solving process is designed to lead a team from identifying a problem through to delivering a solution and evaluating its effectiveness. Without effective time management skills or timeboxing of tasks, it can be easy for a team to get bogged down or be inefficient.

By using a problem solving model and carefully designing your workshop, you can allocate time efficiently and trust that the process will deliver the results you need in a good timeframe.

Time management also comes into play when it comes to rolling out solutions, particularly those that are experimental in nature. Having a clear timeframe for implementing and evaluating solutions is vital for ensuring their success and being able to pivot if necessary.

Improving your skills at problem solving is often a career-long pursuit though there are methods you can use to make the learning process more efficient and to supercharge your problem solving skillset.

Remember that the skills you need to be a great problem solver have a large overlap with those skills you need to be effective in any role. Investing time and effort to develop your active listening or critical thinking skills is valuable in any context. Here are 7 ways to improve your problem solving skills.

Share best practices

Remember that your team is an excellent source of skills, wisdom, and techniques and that you should all take advantage of one another where possible. Best practices that one team has for solving problems, conducting research or making decisions should be shared across the organization. If you have in-house staff that have done active listening training or are data analysis pros, have them lead a training session.

Your team is one of your best resources. Create space and internal processes for the sharing of skills so that you can all grow together.

Ask for help and attend training

Once you’ve figured out you have a skills gap, the next step is to take action to fill that skills gap. That might be by asking your superior for training or coaching, or liaising with team members with that skill set. You might even attend specialized training for certain skills – active listening or critical thinking, for example, are business-critical skills that are regularly offered as part of a training scheme.

Whatever method you choose, remember that taking action of some description is necessary for growth. Whether that means practicing, getting help, attending training or doing some background reading, taking active steps to improve your skills is the way to go.

Learn a process

Problem solving can be complicated, particularly when attempting to solve large problems for the first time. Using a problem solving process helps give structure to your problem solving efforts and focus on creating outcomes, rather than worrying about the format.

Tools such as the seven-step problem solving process above are effective because not only do they feature steps that will help a team solve problems, they also develop skills along the way. Each step asks for people to engage with the process using different skills and in doing so, helps the team learn and grow together. Group processes of varying complexity and purpose can also be found in the SessionLab library of facilitation techniques . Using a tried and tested process and really help ease the learning curve for both those leading such a process, as well as those undergoing the purpose.

Effective teams make decisions about where they should and shouldn’t expend additional effort. By using a problem solving process, you can focus on the things that matter, rather than stumbling towards a solution haphazardly.

Create a feedback loop

Some skills gaps are more obvious than others. It’s possible that your perception of your active listening skills differs from those of your colleagues.

It’s valuable to create a system where team members can provide feedback in an ordered and friendly manner so they can all learn from one another. Only by identifying areas of improvement can you then work to improve them.

Remember that feedback systems require oversight and consideration so that they don’t turn into a place to complain about colleagues. Design the system intelligently so that you encourage the creation of learning opportunities, rather than encouraging people to list their pet peeves.

While practice might not make perfect, it does make the problem solving process easier. If you are having trouble with critical thinking, don’t shy away from doing it. Get involved where you can and stretch those muscles as regularly as possible.

Problem solving skills come more naturally to some than to others and that’s okay. Take opportunities to get involved and see where you can practice your skills in situations outside of a workshop context. Try collaborating in other circumstances at work or conduct data analysis on your own projects. You can often develop those skills you need for problem solving simply by doing them. Get involved!

Use expert exercises and methods

Learn from the best. Our library of 700+ facilitation techniques is full of activities and methods that help develop the skills you need to be an effective problem solver. Check out our templates to see how to approach problem solving and other organizational challenges in a structured and intelligent manner.

There is no single approach to improving problem solving skills, but by using the techniques employed by others you can learn from their example and develop processes that have seen proven results.

Try new ways of thinking and change your mindset

Using tried and tested exercises that you know well can help deliver results, but you do run the risk of missing out on the learning opportunities offered by new approaches. As with the problem solving process, changing your mindset can remove blockages and be used to develop your problem solving skills.

Most teams have members with mixed skill sets and specialties. Mix people from different teams and share skills and different points of view. Teach your customer support team how to use design thinking methods or help your developers with conflict resolution techniques. Try switching perspectives with facilitation techniques like Flip It! or by using new problem solving methodologies or models. Give design thinking, liberating structures or lego serious play a try if you want to try a new approach. You will find that framing problems in new ways and using existing skills in new contexts can be hugely useful for personal development and improving your skillset. It’s also a lot of fun to try new things. Give it a go!

Encountering business challenges and needing to find appropriate solutions is not unique to your organization. Lots of very smart people have developed methods, theories and approaches to help develop problem solving skills and create effective solutions. Learn from them!

Books like The Art of Thinking Clearly , Think Smarter, or Thinking Fast, Thinking Slow are great places to start, though it’s also worth looking at blogs related to organizations facing similar problems to yours, or browsing for success stories. Seeing how Dropbox massively increased growth and working backward can help you see the skills or approach you might be lacking to solve that same problem. Learning from others by reading their stories or approaches can be time-consuming but ultimately rewarding.

A tired, distracted mind is not in the best position to learn new skills. It can be tempted to burn the candle at both ends and develop problem solving skills outside of work. Absolutely use your time effectively and take opportunities for self-improvement, though remember that rest is hugely important and that without letting your brain rest, you cannot be at your most effective.

Creating distance between yourself and the problem you might be facing can also be useful. By letting an idea sit, you can find that a better one presents itself or you can develop it further. Take regular breaks when working and create a space for downtime. Remember that working smarter is preferable to working harder and that self-care is important for any effective learning or improvement process.

Want to design better group processes?

Over to you

Now we’ve explored some of the key problem solving skills and the problem solving steps necessary for an effective process, you’re ready to begin developing more effective solutions and leading problem solving workshops.

Need more inspiration? Check out our post on problem solving activities you can use when guiding a group towards a great solution in your next workshop or meeting. Have questions? Did you have a great problem solving technique you use with your team? Get in touch in the comments below. We’d love to chat!

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Review Article
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Published: 11 January 2023

The effectiveness of collaborative problem solving in promoting students’ critical thinking: A meta-analysis based on empirical literature

Enwei Xu ORCID: orcid.org/0000-0001-6424-8169 1 ,
Wei Wang 1 &
Qingxia Wang 1

Humanities and Social Sciences Communications volume 10 , Article number: 16 ( 2023 ) Cite this article

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Science, technology and society

Collaborative problem-solving has been widely embraced in the classroom instruction of critical thinking, which is regarded as the core of curriculum reform based on key competencies in the field of education as well as a key competence for learners in the 21st century. However, the effectiveness of collaborative problem-solving in promoting students’ critical thinking remains uncertain. This current research presents the major findings of a meta-analysis of 36 pieces of the literature revealed in worldwide educational periodicals during the 21st century to identify the effectiveness of collaborative problem-solving in promoting students’ critical thinking and to determine, based on evidence, whether and to what extent collaborative problem solving can result in a rise or decrease in critical thinking. The findings show that (1) collaborative problem solving is an effective teaching approach to foster students’ critical thinking, with a significant overall effect size (ES = 0.82, z = 12.78, P < 0.01, 95% CI [0.69, 0.95]); (2) in respect to the dimensions of critical thinking, collaborative problem solving can significantly and successfully enhance students’ attitudinal tendencies (ES = 1.17, z = 7.62, P < 0.01, 95% CI[0.87, 1.47]); nevertheless, it falls short in terms of improving students’ cognitive skills, having only an upper-middle impact (ES = 0.70, z = 11.55, P < 0.01, 95% CI[0.58, 0.82]); and (3) the teaching type (chi 2 = 7.20, P < 0.05), intervention duration (chi 2 = 12.18, P < 0.01), subject area (chi 2 = 13.36, P < 0.05), group size (chi 2 = 8.77, P < 0.05), and learning scaffold (chi 2 = 9.03, P < 0.01) all have an impact on critical thinking, and they can be viewed as important moderating factors that affect how critical thinking develops. On the basis of these results, recommendations are made for further study and instruction to better support students’ critical thinking in the context of collaborative problem-solving.

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Introduction

Although critical thinking has a long history in research, the concept of critical thinking, which is regarded as an essential competence for learners in the 21st century, has recently attracted more attention from researchers and teaching practitioners (National Research Council, 2012 ). Critical thinking should be the core of curriculum reform based on key competencies in the field of education (Peng and Deng, 2017 ) because students with critical thinking can not only understand the meaning of knowledge but also effectively solve practical problems in real life even after knowledge is forgotten (Kek and Huijser, 2011 ). The definition of critical thinking is not universal (Ennis, 1989 ; Castle, 2009 ; Niu et al., 2013 ). In general, the definition of critical thinking is a self-aware and self-regulated thought process (Facione, 1990 ; Niu et al., 2013 ). It refers to the cognitive skills needed to interpret, analyze, synthesize, reason, and evaluate information as well as the attitudinal tendency to apply these abilities (Halpern, 2001 ). The view that critical thinking can be taught and learned through curriculum teaching has been widely supported by many researchers (e.g., Kuncel, 2011 ; Leng and Lu, 2020 ), leading to educators’ efforts to foster it among students. In the field of teaching practice, there are three types of courses for teaching critical thinking (Ennis, 1989 ). The first is an independent curriculum in which critical thinking is taught and cultivated without involving the knowledge of specific disciplines; the second is an integrated curriculum in which critical thinking is integrated into the teaching of other disciplines as a clear teaching goal; and the third is a mixed curriculum in which critical thinking is taught in parallel to the teaching of other disciplines for mixed teaching training. Furthermore, numerous measuring tools have been developed by researchers and educators to measure critical thinking in the context of teaching practice. These include standardized measurement tools, such as WGCTA, CCTST, CCTT, and CCTDI, which have been verified by repeated experiments and are considered effective and reliable by international scholars (Facione and Facione, 1992 ). In short, descriptions of critical thinking, including its two dimensions of attitudinal tendency and cognitive skills, different types of teaching courses, and standardized measurement tools provide a complex normative framework for understanding, teaching, and evaluating critical thinking.

Cultivating critical thinking in curriculum teaching can start with a problem, and one of the most popular critical thinking instructional approaches is problem-based learning (Liu et al., 2020 ). Duch et al. ( 2001 ) noted that problem-based learning in group collaboration is progressive active learning, which can improve students’ critical thinking and problem-solving skills. Collaborative problem-solving is the organic integration of collaborative learning and problem-based learning, which takes learners as the center of the learning process and uses problems with poor structure in real-world situations as the starting point for the learning process (Liang et al., 2017 ). Students learn the knowledge needed to solve problems in a collaborative group, reach a consensus on problems in the field, and form solutions through social cooperation methods, such as dialogue, interpretation, questioning, debate, negotiation, and reflection, thus promoting the development of learners’ domain knowledge and critical thinking (Cindy, 2004 ; Liang et al., 2017 ).

Collaborative problem-solving has been widely used in the teaching practice of critical thinking, and several studies have attempted to conduct a systematic review and meta-analysis of the empirical literature on critical thinking from various perspectives. However, little attention has been paid to the impact of collaborative problem-solving on critical thinking. Therefore, the best approach for developing and enhancing critical thinking throughout collaborative problem-solving is to examine how to implement critical thinking instruction; however, this issue is still unexplored, which means that many teachers are incapable of better instructing critical thinking (Leng and Lu, 2020 ; Niu et al., 2013 ). For example, Huber ( 2016 ) provided the meta-analysis findings of 71 publications on gaining critical thinking over various time frames in college with the aim of determining whether critical thinking was truly teachable. These authors found that learners significantly improve their critical thinking while in college and that critical thinking differs with factors such as teaching strategies, intervention duration, subject area, and teaching type. The usefulness of collaborative problem-solving in fostering students’ critical thinking, however, was not determined by this study, nor did it reveal whether there existed significant variations among the different elements. A meta-analysis of 31 pieces of educational literature was conducted by Liu et al. ( 2020 ) to assess the impact of problem-solving on college students’ critical thinking. These authors found that problem-solving could promote the development of critical thinking among college students and proposed establishing a reasonable group structure for problem-solving in a follow-up study to improve students’ critical thinking. Additionally, previous empirical studies have reached inconclusive and even contradictory conclusions about whether and to what extent collaborative problem-solving increases or decreases critical thinking levels. As an illustration, Yang et al. ( 2008 ) carried out an experiment on the integrated curriculum teaching of college students based on a web bulletin board with the goal of fostering participants’ critical thinking in the context of collaborative problem-solving. These authors’ research revealed that through sharing, debating, examining, and reflecting on various experiences and ideas, collaborative problem-solving can considerably enhance students’ critical thinking in real-life problem situations. In contrast, collaborative problem-solving had a positive impact on learners’ interaction and could improve learning interest and motivation but could not significantly improve students’ critical thinking when compared to traditional classroom teaching, according to research by Naber and Wyatt ( 2014 ) and Sendag and Odabasi ( 2009 ) on undergraduate and high school students, respectively.

The above studies show that there is inconsistency regarding the effectiveness of collaborative problem-solving in promoting students’ critical thinking. Therefore, it is essential to conduct a thorough and trustworthy review to detect and decide whether and to what degree collaborative problem-solving can result in a rise or decrease in critical thinking. Meta-analysis is a quantitative analysis approach that is utilized to examine quantitative data from various separate studies that are all focused on the same research topic. This approach characterizes the effectiveness of its impact by averaging the effect sizes of numerous qualitative studies in an effort to reduce the uncertainty brought on by independent research and produce more conclusive findings (Lipsey and Wilson, 2001 ).

This paper used a meta-analytic approach and carried out a meta-analysis to examine the effectiveness of collaborative problem-solving in promoting students’ critical thinking in order to make a contribution to both research and practice. The following research questions were addressed by this meta-analysis:

What is the overall effect size of collaborative problem-solving in promoting students’ critical thinking and its impact on the two dimensions of critical thinking (i.e., attitudinal tendency and cognitive skills)?

How are the disparities between the study conclusions impacted by various moderating variables if the impacts of various experimental designs in the included studies are heterogeneous?

This research followed the strict procedures (e.g., database searching, identification, screening, eligibility, merging, duplicate removal, and analysis of included studies) of Cooper’s ( 2010 ) proposed meta-analysis approach for examining quantitative data from various separate studies that are all focused on the same research topic. The relevant empirical research that appeared in worldwide educational periodicals within the 21st century was subjected to this meta-analysis using Rev-Man 5.4. The consistency of the data extracted separately by two researchers was tested using Cohen’s kappa coefficient, and a publication bias test and a heterogeneity test were run on the sample data to ascertain the quality of this meta-analysis.

Data sources and search strategies

There were three stages to the data collection process for this meta-analysis, as shown in Fig. 1 , which shows the number of articles included and eliminated during the selection process based on the statement and study eligibility criteria.

This flowchart shows the number of records identified, included and excluded in the article.

First, the databases used to systematically search for relevant articles were the journal papers of the Web of Science Core Collection and the Chinese Core source journal, as well as the Chinese Social Science Citation Index (CSSCI) source journal papers included in CNKI. These databases were selected because they are credible platforms that are sources of scholarly and peer-reviewed information with advanced search tools and contain literature relevant to the subject of our topic from reliable researchers and experts. The search string with the Boolean operator used in the Web of Science was “TS = (((“critical thinking” or “ct” and “pretest” or “posttest”) or (“critical thinking” or “ct” and “control group” or “quasi experiment” or “experiment”)) and (“collaboration” or “collaborative learning” or “CSCL”) and (“problem solving” or “problem-based learning” or “PBL”))”. The research area was “Education Educational Research”, and the search period was “January 1, 2000, to December 30, 2021”. A total of 412 papers were obtained. The search string with the Boolean operator used in the CNKI was “SU = (‘critical thinking’*‘collaboration’ + ‘critical thinking’*‘collaborative learning’ + ‘critical thinking’*‘CSCL’ + ‘critical thinking’*‘problem solving’ + ‘critical thinking’*‘problem-based learning’ + ‘critical thinking’*‘PBL’ + ‘critical thinking’*‘problem oriented’) AND FT = (‘experiment’ + ‘quasi experiment’ + ‘pretest’ + ‘posttest’ + ‘empirical study’)” (translated into Chinese when searching). A total of 56 studies were found throughout the search period of “January 2000 to December 2021”. From the databases, all duplicates and retractions were eliminated before exporting the references into Endnote, a program for managing bibliographic references. In all, 466 studies were found.

Second, the studies that matched the inclusion and exclusion criteria for the meta-analysis were chosen by two researchers after they had reviewed the abstracts and titles of the gathered articles, yielding a total of 126 studies.

Third, two researchers thoroughly reviewed each included article’s whole text in accordance with the inclusion and exclusion criteria. Meanwhile, a snowball search was performed using the references and citations of the included articles to ensure complete coverage of the articles. Ultimately, 36 articles were kept.

Two researchers worked together to carry out this entire process, and a consensus rate of almost 94.7% was reached after discussion and negotiation to clarify any emerging differences.

Eligibility criteria

Since not all the retrieved studies matched the criteria for this meta-analysis, eligibility criteria for both inclusion and exclusion were developed as follows:

The publication language of the included studies was limited to English and Chinese, and the full text could be obtained. Articles that did not meet the publication language and articles not published between 2000 and 2021 were excluded.

The research design of the included studies must be empirical and quantitative studies that can assess the effect of collaborative problem-solving on the development of critical thinking. Articles that could not identify the causal mechanisms by which collaborative problem-solving affects critical thinking, such as review articles and theoretical articles, were excluded.

The research method of the included studies must feature a randomized control experiment or a quasi-experiment, or a natural experiment, which have a higher degree of internal validity with strong experimental designs and can all plausibly provide evidence that critical thinking and collaborative problem-solving are causally related. Articles with non-experimental research methods, such as purely correlational or observational studies, were excluded.

The participants of the included studies were only students in school, including K-12 students and college students. Articles in which the participants were non-school students, such as social workers or adult learners, were excluded.

The research results of the included studies must mention definite signs that may be utilized to gauge critical thinking’s impact (e.g., sample size, mean value, or standard deviation). Articles that lacked specific measurement indicators for critical thinking and could not calculate the effect size were excluded.

Data coding design

In order to perform a meta-analysis, it is necessary to collect the most important information from the articles, codify that information’s properties, and convert descriptive data into quantitative data. Therefore, this study designed a data coding template (see Table 1 ). Ultimately, 16 coding fields were retained.

The designed data-coding template consisted of three pieces of information. Basic information about the papers was included in the descriptive information: the publishing year, author, serial number, and title of the paper.

The variable information for the experimental design had three variables: the independent variable (instruction method), the dependent variable (critical thinking), and the moderating variable (learning stage, teaching type, intervention duration, learning scaffold, group size, measuring tool, and subject area). Depending on the topic of this study, the intervention strategy, as the independent variable, was coded into collaborative and non-collaborative problem-solving. The dependent variable, critical thinking, was coded as a cognitive skill and an attitudinal tendency. And seven moderating variables were created by grouping and combining the experimental design variables discovered within the 36 studies (see Table 1 ), where learning stages were encoded as higher education, high school, middle school, and primary school or lower; teaching types were encoded as mixed courses, integrated courses, and independent courses; intervention durations were encoded as 0–1 weeks, 1–4 weeks, 4–12 weeks, and more than 12 weeks; group sizes were encoded as 2–3 persons, 4–6 persons, 7–10 persons, and more than 10 persons; learning scaffolds were encoded as teacher-supported learning scaffold, technique-supported learning scaffold, and resource-supported learning scaffold; measuring tools were encoded as standardized measurement tools (e.g., WGCTA, CCTT, CCTST, and CCTDI) and self-adapting measurement tools (e.g., modified or made by researchers); and subject areas were encoded according to the specific subjects used in the 36 included studies.

The data information contained three metrics for measuring critical thinking: sample size, average value, and standard deviation. It is vital to remember that studies with various experimental designs frequently adopt various formulas to determine the effect size. And this paper used Morris’ proposed standardized mean difference (SMD) calculation formula ( 2008 , p. 369; see Supplementary Table S3 ).

Procedure for extracting and coding data

According to the data coding template (see Table 1 ), the 36 papers’ information was retrieved by two researchers, who then entered them into Excel (see Supplementary Table S1 ). The results of each study were extracted separately in the data extraction procedure if an article contained numerous studies on critical thinking, or if a study assessed different critical thinking dimensions. For instance, Tiwari et al. ( 2010 ) used four time points, which were viewed as numerous different studies, to examine the outcomes of critical thinking, and Chen ( 2013 ) included the two outcome variables of attitudinal tendency and cognitive skills, which were regarded as two studies. After discussion and negotiation during data extraction, the two researchers’ consistency test coefficients were roughly 93.27%. Supplementary Table S2 details the key characteristics of the 36 included articles with 79 effect quantities, including descriptive information (e.g., the publishing year, author, serial number, and title of the paper), variable information (e.g., independent variables, dependent variables, and moderating variables), and data information (e.g., mean values, standard deviations, and sample size). Following that, testing for publication bias and heterogeneity was done on the sample data using the Rev-Man 5.4 software, and then the test results were used to conduct a meta-analysis.

Publication bias test

When the sample of studies included in a meta-analysis does not accurately reflect the general status of research on the relevant subject, publication bias is said to be exhibited in this research. The reliability and accuracy of the meta-analysis may be impacted by publication bias. Due to this, the meta-analysis needs to check the sample data for publication bias (Stewart et al., 2006 ). A popular method to check for publication bias is the funnel plot; and it is unlikely that there will be publishing bias when the data are equally dispersed on either side of the average effect size and targeted within the higher region. The data are equally dispersed within the higher portion of the efficient zone, consistent with the funnel plot connected with this analysis (see Fig. 2 ), indicating that publication bias is unlikely in this situation.

This funnel plot shows the result of publication bias of 79 effect quantities across 36 studies.

Heterogeneity test

To select the appropriate effect models for the meta-analysis, one might use the results of a heterogeneity test on the data effect sizes. In a meta-analysis, it is common practice to gauge the degree of data heterogeneity using the I 2 value, and I 2 ≥ 50% is typically understood to denote medium-high heterogeneity, which calls for the adoption of a random effect model; if not, a fixed effect model ought to be applied (Lipsey and Wilson, 2001 ). The findings of the heterogeneity test in this paper (see Table 2 ) revealed that I 2 was 86% and displayed significant heterogeneity ( P < 0.01). To ensure accuracy and reliability, the overall effect size ought to be calculated utilizing the random effect model.

The analysis of the overall effect size

This meta-analysis utilized a random effect model to examine 79 effect quantities from 36 studies after eliminating heterogeneity. In accordance with Cohen’s criterion (Cohen, 1992 ), it is abundantly clear from the analysis results, which are shown in the forest plot of the overall effect (see Fig. 3 ), that the cumulative impact size of cooperative problem-solving is 0.82, which is statistically significant ( z = 12.78, P < 0.01, 95% CI [0.69, 0.95]), and can encourage learners to practice critical thinking.

This forest plot shows the analysis result of the overall effect size across 36 studies.

In addition, this study examined two distinct dimensions of critical thinking to better understand the precise contributions that collaborative problem-solving makes to the growth of critical thinking. The findings (see Table 3 ) indicate that collaborative problem-solving improves cognitive skills (ES = 0.70) and attitudinal tendency (ES = 1.17), with significant intergroup differences (chi 2 = 7.95, P < 0.01). Although collaborative problem-solving improves both dimensions of critical thinking, it is essential to point out that the improvements in students’ attitudinal tendency are much more pronounced and have a significant comprehensive effect (ES = 1.17, z = 7.62, P < 0.01, 95% CI [0.87, 1.47]), whereas gains in learners’ cognitive skill are slightly improved and are just above average. (ES = 0.70, z = 11.55, P < 0.01, 95% CI [0.58, 0.82]).

The analysis of moderator effect size

The whole forest plot’s 79 effect quantities underwent a two-tailed test, which revealed significant heterogeneity ( I 2 = 86%, z = 12.78, P < 0.01), indicating differences between various effect sizes that may have been influenced by moderating factors other than sampling error. Therefore, exploring possible moderating factors that might produce considerable heterogeneity was done using subgroup analysis, such as the learning stage, learning scaffold, teaching type, group size, duration of the intervention, measuring tool, and the subject area included in the 36 experimental designs, in order to further explore the key factors that influence critical thinking. The findings (see Table 4 ) indicate that various moderating factors have advantageous effects on critical thinking. In this situation, the subject area (chi 2 = 13.36, P < 0.05), group size (chi 2 = 8.77, P < 0.05), intervention duration (chi 2 = 12.18, P < 0.01), learning scaffold (chi 2 = 9.03, P < 0.01), and teaching type (chi 2 = 7.20, P < 0.05) are all significant moderators that can be applied to support the cultivation of critical thinking. However, since the learning stage and the measuring tools did not significantly differ among intergroup (chi 2 = 3.15, P = 0.21 > 0.05, and chi 2 = 0.08, P = 0.78 > 0.05), we are unable to explain why these two factors are crucial in supporting the cultivation of critical thinking in the context of collaborative problem-solving. These are the precise outcomes, as follows:

Various learning stages influenced critical thinking positively, without significant intergroup differences (chi 2 = 3.15, P = 0.21 > 0.05). High school was first on the list of effect sizes (ES = 1.36, P < 0.01), then higher education (ES = 0.78, P < 0.01), and middle school (ES = 0.73, P < 0.01). These results show that, despite the learning stage’s beneficial influence on cultivating learners’ critical thinking, we are unable to explain why it is essential for cultivating critical thinking in the context of collaborative problem-solving.

Different teaching types had varying degrees of positive impact on critical thinking, with significant intergroup differences (chi 2 = 7.20, P < 0.05). The effect size was ranked as follows: mixed courses (ES = 1.34, P < 0.01), integrated courses (ES = 0.81, P < 0.01), and independent courses (ES = 0.27, P < 0.01). These results indicate that the most effective approach to cultivate critical thinking utilizing collaborative problem solving is through the teaching type of mixed courses.

Various intervention durations significantly improved critical thinking, and there were significant intergroup differences (chi 2 = 12.18, P < 0.01). The effect sizes related to this variable showed a tendency to increase with longer intervention durations. The improvement in critical thinking reached a significant level (ES = 0.85, P < 0.01) after more than 12 weeks of training. These findings indicate that the intervention duration and critical thinking’s impact are positively correlated, with a longer intervention duration having a greater effect.

Different learning scaffolds influenced critical thinking positively, with significant intergroup differences (chi 2 = 9.03, P < 0.01). The resource-supported learning scaffold (ES = 0.69, P < 0.01) acquired a medium-to-higher level of impact, the technique-supported learning scaffold (ES = 0.63, P < 0.01) also attained a medium-to-higher level of impact, and the teacher-supported learning scaffold (ES = 0.92, P < 0.01) displayed a high level of significant impact. These results show that the learning scaffold with teacher support has the greatest impact on cultivating critical thinking.

Various group sizes influenced critical thinking positively, and the intergroup differences were statistically significant (chi 2 = 8.77, P < 0.05). Critical thinking showed a general declining trend with increasing group size. The overall effect size of 2–3 people in this situation was the biggest (ES = 0.99, P < 0.01), and when the group size was greater than 7 people, the improvement in critical thinking was at the lower-middle level (ES < 0.5, P < 0.01). These results show that the impact on critical thinking is positively connected with group size, and as group size grows, so does the overall impact.

Various measuring tools influenced critical thinking positively, with significant intergroup differences (chi 2 = 0.08, P = 0.78 > 0.05). In this situation, the self-adapting measurement tools obtained an upper-medium level of effect (ES = 0.78), whereas the complete effect size of the standardized measurement tools was the largest, achieving a significant level of effect (ES = 0.84, P < 0.01). These results show that, despite the beneficial influence of the measuring tool on cultivating critical thinking, we are unable to explain why it is crucial in fostering the growth of critical thinking by utilizing the approach of collaborative problem-solving.

Different subject areas had a greater impact on critical thinking, and the intergroup differences were statistically significant (chi 2 = 13.36, P < 0.05). Mathematics had the greatest overall impact, achieving a significant level of effect (ES = 1.68, P < 0.01), followed by science (ES = 1.25, P < 0.01) and medical science (ES = 0.87, P < 0.01), both of which also achieved a significant level of effect. Programming technology was the least effective (ES = 0.39, P < 0.01), only having a medium-low degree of effect compared to education (ES = 0.72, P < 0.01) and other fields (such as language, art, and social sciences) (ES = 0.58, P < 0.01). These results suggest that scientific fields (e.g., mathematics, science) may be the most effective subject areas for cultivating critical thinking utilizing the approach of collaborative problem-solving.

The effectiveness of collaborative problem solving with regard to teaching critical thinking

According to this meta-analysis, using collaborative problem-solving as an intervention strategy in critical thinking teaching has a considerable amount of impact on cultivating learners’ critical thinking as a whole and has a favorable promotional effect on the two dimensions of critical thinking. According to certain studies, collaborative problem solving, the most frequently used critical thinking teaching strategy in curriculum instruction can considerably enhance students’ critical thinking (e.g., Liang et al., 2017 ; Liu et al., 2020 ; Cindy, 2004 ). This meta-analysis provides convergent data support for the above research views. Thus, the findings of this meta-analysis not only effectively address the first research query regarding the overall effect of cultivating critical thinking and its impact on the two dimensions of critical thinking (i.e., attitudinal tendency and cognitive skills) utilizing the approach of collaborative problem-solving, but also enhance our confidence in cultivating critical thinking by using collaborative problem-solving intervention approach in the context of classroom teaching.

Furthermore, the associated improvements in attitudinal tendency are much stronger, but the corresponding improvements in cognitive skill are only marginally better. According to certain studies, cognitive skill differs from the attitudinal tendency in classroom instruction; the cultivation and development of the former as a key ability is a process of gradual accumulation, while the latter as an attitude is affected by the context of the teaching situation (e.g., a novel and exciting teaching approach, challenging and rewarding tasks) (Halpern, 2001 ; Wei and Hong, 2022 ). Collaborative problem-solving as a teaching approach is exciting and interesting, as well as rewarding and challenging; because it takes the learners as the focus and examines problems with poor structure in real situations, and it can inspire students to fully realize their potential for problem-solving, which will significantly improve their attitudinal tendency toward solving problems (Liu et al., 2020 ). Similar to how collaborative problem-solving influences attitudinal tendency, attitudinal tendency impacts cognitive skill when attempting to solve a problem (Liu et al., 2020 ; Zhang et al., 2022 ), and stronger attitudinal tendencies are associated with improved learning achievement and cognitive ability in students (Sison, 2008 ; Zhang et al., 2022 ). It can be seen that the two specific dimensions of critical thinking as well as critical thinking as a whole are affected by collaborative problem-solving, and this study illuminates the nuanced links between cognitive skills and attitudinal tendencies with regard to these two dimensions of critical thinking. To fully develop students’ capacity for critical thinking, future empirical research should pay closer attention to cognitive skills.

The moderating effects of collaborative problem solving with regard to teaching critical thinking

In order to further explore the key factors that influence critical thinking, exploring possible moderating effects that might produce considerable heterogeneity was done using subgroup analysis. The findings show that the moderating factors, such as the teaching type, learning stage, group size, learning scaffold, duration of the intervention, measuring tool, and the subject area included in the 36 experimental designs, could all support the cultivation of collaborative problem-solving in critical thinking. Among them, the effect size differences between the learning stage and measuring tool are not significant, which does not explain why these two factors are crucial in supporting the cultivation of critical thinking utilizing the approach of collaborative problem-solving.

In terms of the learning stage, various learning stages influenced critical thinking positively without significant intergroup differences, indicating that we are unable to explain why it is crucial in fostering the growth of critical thinking.

Although high education accounts for 70.89% of all empirical studies performed by researchers, high school may be the appropriate learning stage to foster students’ critical thinking by utilizing the approach of collaborative problem-solving since it has the largest overall effect size. This phenomenon may be related to student’s cognitive development, which needs to be further studied in follow-up research.

With regard to teaching type, mixed course teaching may be the best teaching method to cultivate students’ critical thinking. Relevant studies have shown that in the actual teaching process if students are trained in thinking methods alone, the methods they learn are isolated and divorced from subject knowledge, which is not conducive to their transfer of thinking methods; therefore, if students’ thinking is trained only in subject teaching without systematic method training, it is challenging to apply to real-world circumstances (Ruggiero, 2012 ; Hu and Liu, 2015 ). Teaching critical thinking as mixed course teaching in parallel to other subject teachings can achieve the best effect on learners’ critical thinking, and explicit critical thinking instruction is more effective than less explicit critical thinking instruction (Bensley and Spero, 2014 ).

In terms of the intervention duration, with longer intervention times, the overall effect size shows an upward tendency. Thus, the intervention duration and critical thinking’s impact are positively correlated. Critical thinking, as a key competency for students in the 21st century, is difficult to get a meaningful improvement in a brief intervention duration. Instead, it could be developed over a lengthy period of time through consistent teaching and the progressive accumulation of knowledge (Halpern, 2001 ; Hu and Liu, 2015 ). Therefore, future empirical studies ought to take these restrictions into account throughout a longer period of critical thinking instruction.

With regard to group size, a group size of 2–3 persons has the highest effect size, and the comprehensive effect size decreases with increasing group size in general. This outcome is in line with some research findings; as an example, a group composed of two to four members is most appropriate for collaborative learning (Schellens and Valcke, 2006 ). However, the meta-analysis results also indicate that once the group size exceeds 7 people, small groups cannot produce better interaction and performance than large groups. This may be because the learning scaffolds of technique support, resource support, and teacher support improve the frequency and effectiveness of interaction among group members, and a collaborative group with more members may increase the diversity of views, which is helpful to cultivate critical thinking utilizing the approach of collaborative problem-solving.

With regard to the learning scaffold, the three different kinds of learning scaffolds can all enhance critical thinking. Among them, the teacher-supported learning scaffold has the largest overall effect size, demonstrating the interdependence of effective learning scaffolds and collaborative problem-solving. This outcome is in line with some research findings; as an example, a successful strategy is to encourage learners to collaborate, come up with solutions, and develop critical thinking skills by using learning scaffolds (Reiser, 2004 ; Xu et al., 2022 ); learning scaffolds can lower task complexity and unpleasant feelings while also enticing students to engage in learning activities (Wood et al., 2006 ); learning scaffolds are designed to assist students in using learning approaches more successfully to adapt the collaborative problem-solving process, and the teacher-supported learning scaffolds have the greatest influence on critical thinking in this process because they are more targeted, informative, and timely (Xu et al., 2022 ).

With respect to the measuring tool, despite the fact that standardized measurement tools (such as the WGCTA, CCTT, and CCTST) have been acknowledged as trustworthy and effective by worldwide experts, only 54.43% of the research included in this meta-analysis adopted them for assessment, and the results indicated no intergroup differences. These results suggest that not all teaching circumstances are appropriate for measuring critical thinking using standardized measurement tools. “The measuring tools for measuring thinking ability have limits in assessing learners in educational situations and should be adapted appropriately to accurately assess the changes in learners’ critical thinking.”, according to Simpson and Courtney ( 2002 , p. 91). As a result, in order to more fully and precisely gauge how learners’ critical thinking has evolved, we must properly modify standardized measuring tools based on collaborative problem-solving learning contexts.

With regard to the subject area, the comprehensive effect size of science departments (e.g., mathematics, science, medical science) is larger than that of language arts and social sciences. Some recent international education reforms have noted that critical thinking is a basic part of scientific literacy. Students with scientific literacy can prove the rationality of their judgment according to accurate evidence and reasonable standards when they face challenges or poorly structured problems (Kyndt et al., 2013 ), which makes critical thinking crucial for developing scientific understanding and applying this understanding to practical problem solving for problems related to science, technology, and society (Yore et al., 2007 ).

Suggestions for critical thinking teaching

Other than those stated in the discussion above, the following suggestions are offered for critical thinking instruction utilizing the approach of collaborative problem-solving.

First, teachers should put a special emphasis on the two core elements, which are collaboration and problem-solving, to design real problems based on collaborative situations. This meta-analysis provides evidence to support the view that collaborative problem-solving has a strong synergistic effect on promoting students’ critical thinking. Asking questions about real situations and allowing learners to take part in critical discussions on real problems during class instruction are key ways to teach critical thinking rather than simply reading speculative articles without practice (Mulnix, 2012 ). Furthermore, the improvement of students’ critical thinking is realized through cognitive conflict with other learners in the problem situation (Yang et al., 2008 ). Consequently, it is essential for teachers to put a special emphasis on the two core elements, which are collaboration and problem-solving, and design real problems and encourage students to discuss, negotiate, and argue based on collaborative problem-solving situations.

Second, teachers should design and implement mixed courses to cultivate learners’ critical thinking, utilizing the approach of collaborative problem-solving. Critical thinking can be taught through curriculum instruction (Kuncel, 2011 ; Leng and Lu, 2020 ), with the goal of cultivating learners’ critical thinking for flexible transfer and application in real problem-solving situations. This meta-analysis shows that mixed course teaching has a highly substantial impact on the cultivation and promotion of learners’ critical thinking. Therefore, teachers should design and implement mixed course teaching with real collaborative problem-solving situations in combination with the knowledge content of specific disciplines in conventional teaching, teach methods and strategies of critical thinking based on poorly structured problems to help students master critical thinking, and provide practical activities in which students can interact with each other to develop knowledge construction and critical thinking utilizing the approach of collaborative problem-solving.

Third, teachers should be more trained in critical thinking, particularly preservice teachers, and they also should be conscious of the ways in which teachers’ support for learning scaffolds can promote critical thinking. The learning scaffold supported by teachers had the greatest impact on learners’ critical thinking, in addition to being more directive, targeted, and timely (Wood et al., 2006 ). Critical thinking can only be effectively taught when teachers recognize the significance of critical thinking for students’ growth and use the proper approaches while designing instructional activities (Forawi, 2016 ). Therefore, with the intention of enabling teachers to create learning scaffolds to cultivate learners’ critical thinking utilizing the approach of collaborative problem solving, it is essential to concentrate on the teacher-supported learning scaffolds and enhance the instruction for teaching critical thinking to teachers, especially preservice teachers.

Implications and limitations

There are certain limitations in this meta-analysis, but future research can correct them. First, the search languages were restricted to English and Chinese, so it is possible that pertinent studies that were written in other languages were overlooked, resulting in an inadequate number of articles for review. Second, these data provided by the included studies are partially missing, such as whether teachers were trained in the theory and practice of critical thinking, the average age and gender of learners, and the differences in critical thinking among learners of various ages and genders. Third, as is typical for review articles, more studies were released while this meta-analysis was being done; therefore, it had a time limit. With the development of relevant research, future studies focusing on these issues are highly relevant and needed.

Conclusions

The subject of the magnitude of collaborative problem-solving’s impact on fostering students’ critical thinking, which received scant attention from other studies, was successfully addressed by this study. The question of the effectiveness of collaborative problem-solving in promoting students’ critical thinking was addressed in this study, which addressed a topic that had gotten little attention in earlier research. The following conclusions can be made:

Regarding the results obtained, collaborative problem solving is an effective teaching approach to foster learners’ critical thinking, with a significant overall effect size (ES = 0.82, z = 12.78, P < 0.01, 95% CI [0.69, 0.95]). With respect to the dimensions of critical thinking, collaborative problem-solving can significantly and effectively improve students’ attitudinal tendency, and the comprehensive effect is significant (ES = 1.17, z = 7.62, P < 0.01, 95% CI [0.87, 1.47]); nevertheless, it falls short in terms of improving students’ cognitive skills, having only an upper-middle impact (ES = 0.70, z = 11.55, P < 0.01, 95% CI [0.58, 0.82]).

As demonstrated by both the results and the discussion, there are varying degrees of beneficial effects on students’ critical thinking from all seven moderating factors, which were found across 36 studies. In this context, the teaching type (chi 2 = 7.20, P < 0.05), intervention duration (chi 2 = 12.18, P < 0.01), subject area (chi 2 = 13.36, P < 0.05), group size (chi 2 = 8.77, P < 0.05), and learning scaffold (chi 2 = 9.03, P < 0.01) all have a positive impact on critical thinking, and they can be viewed as important moderating factors that affect how critical thinking develops. Since the learning stage (chi 2 = 3.15, P = 0.21 > 0.05) and measuring tools (chi 2 = 0.08, P = 0.78 > 0.05) did not demonstrate any significant intergroup differences, we are unable to explain why these two factors are crucial in supporting the cultivation of critical thinking in the context of collaborative problem-solving.

Data availability

All data generated or analyzed during this study are included within the article and its supplementary information files, and the supplementary information files are available in the Dataverse repository: https://doi.org/10.7910/DVN/IPFJO6 .

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Acknowledgements

This research was supported by the graduate scientific research and innovation project of Xinjiang Uygur Autonomous Region named “Research on in-depth learning of high school information technology courses for the cultivation of computing thinking” (No. XJ2022G190) and the independent innovation fund project for doctoral students of the College of Educational Science of Xinjiang Normal University named “Research on project-based teaching of high school information technology courses from the perspective of discipline core literacy” (No. XJNUJKYA2003).

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Xu, E., Wang, W. & Wang, Q. The effectiveness of collaborative problem solving in promoting students’ critical thinking: A meta-analysis based on empirical literature. Humanit Soc Sci Commun 10 , 16 (2023). https://doi.org/10.1057/s41599-023-01508-1

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Helping Students Hone Their Critical Thinking Skills

Used consistently, these strategies can help middle and high school teachers guide students to improve much-needed skills.

Middle school students involved in a classroom discussion

Critical thinking skills are important in every discipline, at and beyond school. From managing money to choosing which candidates to vote for in elections to making difficult career choices, students need to be prepared to take in, synthesize, and act on new information in a world that is constantly changing.

While critical thinking might seem like an abstract idea that is tough to directly instruct, there are many engaging ways to help students strengthen these skills through active learning.

Make Time for Metacognitive Reflection

Create space for students to both reflect on their ideas and discuss the power of doing so. Show students how they can push back on their own thinking to analyze and question their assumptions. Students might ask themselves, “Why is this the best answer? What information supports my answer? What might someone with a counterargument say?”

Through this reflection, students and teachers (who can model reflecting on their own thinking) gain deeper understandings of their ideas and do a better job articulating their beliefs. In a world that is go-go-go, it is important to help students understand that it is OK to take a breath and think about their ideas before putting them out into the world. And taking time for reflection helps us more thoughtfully consider others’ ideas, too.

Teach Reasoning Skills

Reasoning skills are another key component of critical thinking, involving the abilities to think logically, evaluate evidence, identify assumptions, and analyze arguments. Students who learn how to use reasoning skills will be better equipped to make informed decisions, form and defend opinions, and solve problems.

One way to teach reasoning is to use problem-solving activities that require students to apply their skills to practical contexts. For example, give students a real problem to solve, and ask them to use reasoning skills to develop a solution. They can then present their solution and defend their reasoning to the class and engage in discussion about whether and how their thinking changed when listening to peers’ perspectives.

A great example I have seen involved students identifying an underutilized part of their school and creating a presentation about one way to redesign it. This project allowed students to feel a sense of connection to the problem and come up with creative solutions that could help others at school. For more examples, you might visit PBS’s Design Squad , a resource that brings to life real-world problem-solving.

Ask Open-Ended Questions

Moving beyond the repetition of facts, critical thinking requires students to take positions and explain their beliefs through research, evidence, and explanations of credibility.

When we pose open-ended questions, we create space for classroom discourse inclusive of diverse, perhaps opposing, ideas—grounds for rich exchanges that support deep thinking and analysis.

For example, “How would you approach the problem?” and “Where might you look to find resources to address this issue?” are two open-ended questions that position students to think less about the “right” answer and more about the variety of solutions that might already exist.

Journaling, whether digitally or physically in a notebook, is another great way to have students answer these open-ended prompts—giving them time to think and organize their thoughts before contributing to a conversation, which can ensure that more voices are heard.

Once students process in their journal, small group or whole class conversations help bring their ideas to life. Discovering similarities between answers helps reveal to students that they are not alone, which can encourage future participation in constructive civil discourse.

Teach Information Literacy

Education has moved far past the idea of “Be careful of what is on Wikipedia, because it might not be true.” With AI innovations making their way into classrooms, teachers know that informed readers must question everything.

Understanding what is and is not a reliable source and knowing how to vet information are important skills for students to build and utilize when making informed decisions. You might start by introducing the idea of bias: Articles, ads, memes, videos, and every other form of media can push an agenda that students may not see on the surface. Discuss credibility, subjectivity, and objectivity, and look at examples and nonexamples of trusted information to prepare students to be well-informed members of a democracy.

One of my favorite lessons is about the Pacific Northwest tree octopus . This project asks students to explore what appears to be a very real website that provides information on this supposedly endangered animal. It is a wonderful, albeit over-the-top, example of how something might look official even when untrue, revealing that we need critical thinking to break down “facts” and determine the validity of the information we consume.

A fun extension is to have students come up with their own website or newsletter about something going on in school that is untrue. Perhaps a change in dress code that requires everyone to wear their clothes inside out or a change to the lunch menu that will require students to eat brussels sprouts every day.

Giving students the ability to create their own falsified information can help them better identify it in other contexts. Understanding that information can be “too good to be true” can help them identify future falsehoods.

Provide Diverse Perspectives

Consider how to keep the classroom from becoming an echo chamber. If students come from the same community, they may have similar perspectives. And those who have differing perspectives may not feel comfortable sharing them in the face of an opposing majority.

To support varying viewpoints, bring diverse voices into the classroom as much as possible, especially when discussing current events. Use primary sources: videos from YouTube, essays and articles written by people who experienced current events firsthand, documentaries that dive deeply into topics that require some nuance, and any other resources that provide a varied look at topics.

I like to use the Smithsonian “OurStory” page , which shares a wide variety of stories from people in the United States. The page on Japanese American internment camps is very powerful because of its first-person perspectives.

Practice Makes Perfect

To make the above strategies and thinking routines a consistent part of your classroom, spread them out—and build upon them—over the course of the school year. You might challenge students with information and/or examples that require them to use their critical thinking skills; work these skills explicitly into lessons, projects, rubrics, and self-assessments; or have students practice identifying misinformation or unsupported arguments.

Critical thinking is not learned in isolation. It needs to be explored in English language arts, social studies, science, physical education, math. Every discipline requires students to take a careful look at something and find the best solution. Often, these skills are taken for granted, viewed as a by-product of a good education, but true critical thinking doesn’t just happen. It requires consistency and commitment.

In a moment when information and misinformation abound, and students must parse reams of information, it is imperative that we support and model critical thinking in the classroom to support the development of well-informed citizens.

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Pennsylvania State University, State College, USA

Justin Mason

University of Florida, Gainesville, USA

In this study, the authors investigated if two distinct types of video gameplay improved undergraduates’ problem-solving skills. Two groups of student participants were recruited to play either a roleplaying video game (World of Warcraft; experimental group) or a brain-training video game (CogniFit; control group). Participants were measured on their problem-solving skills before and after 20 hours of video gameplay. Two measures were used to assess problem-solving skills for this study, the Tower of Hanoi and The PISA Problem Solving Test. The Tower of Hanoi measured the rule application component of problem-solving skills and the PISA Problem Solving test measured transfer of problem-solving skills from video gameplay to novel scenarios on the test. No significant differences were found between the two groups on either problem-solving measure. Implications for future studies on game- based learning are discussed.

Introduction

Video games are played by more than half of the U.S population and the video game industry generated $36 billion in 2018 ( ESA, 2018 ). Given the popularity and success of the video game industry, game- based scholars are exploring how well-designed video games can be used to improve a wide range of knowledge, skills, and abilities referred to as game-based learning (GBL). Proponents of GBL argue that well-designed video games are grounded by active participation and interaction as the focal point of the learner experience and can lead to changes in behavior and cognition ( Ifenthaler, Eseryel, & Ge, 2012 ; Shute et al., 2019 ). Moreover, well-designed video games immerse players in environments that can provide a framework for learning experiences by promoting engagement and transfer from simulated worlds to the natural world ( Dede, 2009 ).

Current American students are not receiving adequate exposure to authentic ill-structured problem-solving scenarios in their classrooms, and schools need to address the acquisition of problem-solving skills for students in the 21st century ( Shute & Wang, 2016 ). American students trail their international counterparts in problem-solving skills on the Program for International Student Assessment (PISA) Problem Solving Test. Furthermore, American business leaders complain about recent college graduates’ lack of problem-solving skills. Two surveys conducted by the Association of American Colleges and Universities of business leaders and students indicated that problem-solving skills are increasingly desirable for American employers, but only 38% of employers reported that recently hired American college graduates could analyze and solve complex problems while working ( Hart Associates, 2018 ).

Researchers of video game studies find that gameplay can be positively associated with the improvement of problem-solving skills ( Shute, Ventura, & Ke, 2015 ; Spires et al., 2011 ). However, current discourse in the field of gameplay and problem-solving skills centers primarily on descriptive research ( Eseryel et al., 2014 ) which can be summarized based on the following premise: video games require players to solve problems, and over time, playing video games will lead to improved problem- solving skills ( Hung & Van Eck, 2010 ). Descriptive research is important to argue that video games support problem-solving skills, but further empirical research is needed to demonstrate whether problem-solving skills are acquired through video gameplay. This research study addressed whether two distinct types of video gameplay empirically affects undergraduates’ problem-solving skills.

Video Games and Problem-Solving Skills

According to Mayer and Wittrock’s (2006) definition, problem solving includes four central characteristics: (1) occurs internally to the problem solver’s cognitive system; (2) is a process that involves conceptualizing and manipulating knowledge; (3) is goal directed; and (4) is dependent on the knowledge and skills of the problem solver to establish the difficulty in which obstacles must be overcome to reach a solution. Unlike the well-structured problems that students face in formal learning settings, well-designed games provide students with challenging scenarios that promote problem-solving skills by requiring players to generate new knowledge from challenging scenarios within interactive environments, while also providing immersive gameplay that includes ongoing feedback for the players to hone their problem-solving skills over time ( Van Eck, Shute, & Rieber, 2017 ). Rules govern video gameplay mechanics and one component of problem solving is the ability to apply existing rules in the problem space known as rule application ( Shute et al., 2015 ). One example of a rule application is found in the well-researched problem-solving puzzle the Tower of Hanoi ( Huyck & Kreivenas, 2018 ; Schiff & Vakil, 2015 ; TOH, 2019 ). The rule application component of problem-solving skill is one of the dependent variables in this study. Rule application refers to the problem-solver’s representation of the problem space through direct action, which is critical to problem solving ( Van Eck et al., 2017 ).

Literature Review

Video gameplay and transfer.

Researchers contend that the hidden power of well-designed video games is their potential to address higher-level learning, like retention, transfer, and problem-solving skills ( Gee, 2008 ; Shute & Wang, 2015 ). Retention is the ability to remember the presented information and correctly recall it when needed, while transfer is the ability to apply previously learned information in a novel situation ( Stiller & Schworm, 2019 ). Possible outcomes of playing video games may include the improvement of collaborative problem-solving skills, confidence, and leadership skills that are transferable to the workforce environment. Recent research on video game training studies and transfer of cognitive and noncognitive skills indicates that gameplay is positively associated with the improvement of attention, problem-solving skills, persistence ( Green & Bavelier, 2012 ; Rowe et al., 2011 ; Shute et al., 2015 ; Ventura et al., 2013 ), executive functions ( Oei & Patterson, 2014 ), and hypothesis testing strategies ( Spires et al., 2011 ). However, other researchers have found null effects of video gameplay and transfer of cognitive skills ( Ackerman, et al., 2010 ; Baniqued, Kranz, et al., 2013 ; Boot et al., 2008 ).

A recent meta-analysis of brain-training interventions found that brain-training interventions can improve performance on trained tasks but there were fewer examples of interventions indicating improved performance on closely related tasks, and minimal evidence that training enhances performance on daily cognitive abilities ( Simons et al., 2016 ). Among those finding null effects, questions were raised about the methodological shortcomings of video game training and transfer studies that are common pitfalls in experimental trials. Some of the pitfalls included failing to report full methods used in a study and lack of an effective active control condition that can expect to see similar improvement in competencies as the experimental group ( Baniqued et al., 2013 ; Boot, 2015 ; Boot, Blakely & Simons, 2011 ). Unless researchers define recruitment methods for participants and their gaming expertise (novice vs. expert), as well as compare active control groups with experimental groups receiving equal training games, then differential improvement is indeterminable ( Boot et al., 2013 ; Shute et al., 2015 ). The recruitment approach is outlined in the Method section.

Motivation for Selection of Games

The video games selected for this research study were based on the problem-solving skills players exercise and acquire through gameplay that were aligned with the problem-solving skills assessed on the external measures, the PISA Problem Solving Test and the Tower of Hanoi (TOH). Well-designed video games include sound learning principles embedded within gameplay such as requiring players to solve complex problems which can then be applied to other learning contexts ( Lieberman et al., 2014 ). In this study, the authors examined the effects of playing World of Warcraft ( Activision Blizzard, 2019 ) and CogniFit ( CogniFit, 2019 ) for twenty hours on undergraduates’ problem-solving skills (rule application and problem-solving transfer). The inclusion of CogniFit addresses a main concern of game-based research which is the lack of an active control condition to determine differential improvement ( Boot et al., 2013 ).

Problem-Solving and Video Gameplay Model

The authors have identified observable in-game behaviors (i.e., indicators) during gameplay that provide evidence for each of the problem-solving processes on the PISA Problem Solving Test. The process included playing each video game extensively, checking community forums for solutions to the most challenging problems for each game, and viewing experts’ gameplay video channel streams on YouTube. After generating a list of credible indicators, those selected were based on the following criteria: (a) relevance to the PISA problem solving levels of proficiency and (b) verifiable through gameplay mechanics. Examples of indicators for the PISA problem-solving processes for each game are listed in Tables 1 and and2. 2 . The purpose of developing the problem-solving behavior model is to operationalize the indicators of gameplay that align with the cognitive processes being assessed on the PISA test (i.e., Exploring and Understanding, Representing and Formulating). The PISA Problem Solving Test contains questions representing six levels of proficiency: Level 1 is the most limited form of problem-solving ability such as rule application (solving problems with simple rules or constraints) and Level 6 is the complex form of problem-solving ability (executing strategies and developing mental models to solve problems). The PISA test will determine whether there is transfer of problem-solving skills from video gameplay to novel scenarios.

Examples of indicators for each PISA problem-solving process in Warcraft

Examples of indicators for each PISA problem-solving process in CogniFit

World of warcraft

Massive multiplayer online role-playing games (MMORPGs) require players to manage resources, adapt playstyle to the environment, test new skills and abilities, identify and apply rules to solve problems as well as explore the story of the game through questing. MMORPGs like Warcraft provide gameplay experiences that are analogous to meaningful instruction by offering complex multifaceted problems that require model-based reasoning—understanding interrelated components of a system, and feedback mechanisms among the components to find the best solutions to problems that arise using available tools and resources in a given environment ( Chinn & Malhotra, 2002 ; Steinkuehler & Chmiel, 2006 ). Therefore, if MMORPGs provide an authentic sense of inquiry into solving problems through gameplay, then it is worth testing whether these gameplay experiences transfer to novel problem-solving scenarios.

One specific example of transfer from gameplay in the MMORPG Warcraft to a natural context concerns the problem of reducing travel time. When players enter the game environment, they must account for extended travel time between different activities such as exploration, questing, and combat. To solve this problem, players are given a tool that can be accessed on their user interface by pressing (M) on their keyboard, which opens the map. Listed on the map are designated flight paths (FPs) that act as a taxi service for players. The image in Figure 1 indicates the various FPs a player has unlocked on their world map as well as those that have yet to be discovered ( Activision Blizzard, 2019 ). The flight path is a handy tool because it connects the goal of completing quests as soon as possible to earn rewards with the knowledge that using flight paths greatly reduces travel time between quests. Greatly reducing travel time results in a more efficient way to complete many of the sub goals in the game, and as noted by Shute and Wang (2016) the use of tools and resources efficiently is an important part of problem solving during gameplay.

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Player map listing flight path locations in World of Warcraft (2019)

Now, consider one of the questions being assessed on an external measure in the study, the PISA Problem Solving Test. Individuals are given a map that shows the roads between each city, a partially filled-in key that shows distances between cities in kilometers, and the overall layout of the area. The purpose of this question is to assess how individuals calculate the shortest distance from one city to another. To solve the problem, individuals are required to calculate the distance between the two cities of Nuben and Kado using the resources available. This is the same kind of problem that Warcraft players experience during gameplay when travelling between locations to complete quests. Both problem scenarios share the same overlapping components, the ability of the problem solver to use given tools and resources efficiently to find the most direct route that reduces travel time between two separate locations. Figure 2 illustrates this problem scenario on the PISA test ( OECD, 2003 ).

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Problem scenario for planning the best route for a trip from PISA (2003)

The brain training game CogniFit claims to have developed a patented system that measures, trains, and monitors cognitive skills like rule application, attention, memory, and visual perception and their relation to neurological pathologies. According to the CogniFit (2019) website the company states there are transfer effects from their mini games to problem solving in the natural world. The brain training game is selected as an active control condition based on this claim as well as repeated practice of rule application embedded into the gameplay experience.

One example of rule application in the brain training game CogniFit occurs in the mini-game Gem Breaker 3D. This mini-game requires players to direct a paddle back and forth across the screen to bounce a ball off the paddle that breaks the gem blocks without letting the ball touch the bottom of the screen. The initial tutorial informs players that improvement of their hand-eye coordination and processing speed skills are emphasized through gameplay with over 100 levels available to master. Feedback is provided to players with a score for each level showing where they can improve. Once all gem blocks are broken the level is completed and a new level begins. However, each player only has access to 4 balls for each level, and if they lose, the game reverts to the beginning. The tutorial shows players how to use the mouse to control the paddle back and forth across the screen while the spacebar launches the ball. Once a gem is broken there is a chance for a power-up to be gained such as shooting multiple balls, explosives, missiles, side quests or power-ups. Figure 3 illustrates the rules of the mini-game in Gem Breaker 3D ( CogniFit, 2019 ).

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Rules for the mini-game Gem Breaker 3D listed in the initial tutorial (2019)

Rule application occurs when playing the TOH and requires one to move an entire stack of disks (i.e., a number between 3 and 8) of varied sizes from one of three rods to another. While playing, players are constrained by the following rules: (1) only one disk can be moved at a time; (2) no disk can be placed on a smaller one; (3) only the uppermost disk can be moved on a stack. Rule application is demonstrated by the problem solver in the TOH by configuring the disks and the rods to reach a solution in the problem space. By configuring the disks onto the rods, each move of a disk indicates the problem solver attempting to creatively apply the rules, which is vital to problem solving ( Shute et al., 2019 ). Figure 4 illustrates the problem space in an online version of the TOH (2019) .

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Problem space in an online version of the Tower of Hanoi puzzle with 5 disks (2019)

Both video games require players to apply rules to solve problems and rule application is a component of problem solving ( Van Eck et al., 2017 ). As an example, Warcraft players learn that they can only cast certain spells in combat while standing still or that eating and drinking food while sitting down hastens the regeneration of health. Similarly, when playing the mini-game Gem Breaker 3D in CogniFit players use a paddle and a ball to break bricks. One of the first rules players encounter in the game is that they can only move the paddle left or right across the screen or that bonus bricks have special effects like increasing ball speed. The rules are more explicit in CogniFit than Warcraft so brain-training gameplay may promote better performance on solving the TOH. Each move with the paddle and ball is an example of applying the rules, and this is frequently done during gameplay in CogniFit .

However, CogniFit mini-games lack some of the salient gameplay features in Warcraft such as roleplaying gameplay, meaningful interactions with other players, and richly designed problem spaces that GBL scholars suggest are important to the transfer of problem-solving skills from video gameplay to novel contexts measured on the PISA Problem Solving Test. Warcraft gameplay provides players with repeated practice to solve authentic ill-structured problems in rich detailed problem-solving scenarios that may be better suited for transfer to novel scenarios on the test.

Research Questions

After describing the video gameplay conditions of Warcraft and CogniFit as well as reviewing the literature on problem-solving skills, the authors seek to answer the following research questions:

Is there a change, from pretest to posttest, on the rule-application component of problem solving, after 20 hours of video gameplay, on either a role playing or brain-training video game?
Does an immersive, collaborative role-playing video game promote transfer of problem-solving skills to novel scenarios better than a brain-training video game for undergraduates after 20 hours of video gameplay?

Setting and Participants

For this study, 91 undergraduate student participants (M Age = 19.32; SD Age = 1.43) were recruited to participate in this study and completed the initial questionnaire for the study, assessing: age, gender, ethnicity, major, and video games played daily. Participants were not invited to participate if they were not students at the data-collecting institution, were not 18–23 years old, or if they reported playing 30 or more minutes of Warcraft or CogniFit . 56 participants were randomly assigned to either the experimental group Warcraft or the control group CogniFit , yet only 34 completed the study ( n = 17 per group). Participant attrition for both groups were attributed to lack of time to complete the study or being too busy with schoolwork. Given the nature of our research questions assessing change as a function of training, subsequently presented analyses only include data from the 34 participants (17 males and 17 females) who completed the study (M Age = 19.44; SD Age = 1.41).

The independent variable in this research study is the video game with two levels: a roleplaying video game ( Warcraft ) and a brain-training video game ( CogniFit ). The video games provide players with repeated problem-solving scenarios requiring players to engage in problem-solving processes. The dependent variable measured for this study is problem-solving skill. One measure assessed the component of rule application of problem solving to solve a puzzle which is the TOH. The second measure assessed problem-solving in novel scenarios which is the PISA Problem Solving Test. Both groups were assessed on the TOH and the PISA Problem Solving Test. The TOH was used to assess research question 1 and the PISA Problem Solving Test was used to assess research question 2.

The Tower of Hanoi

Recall, the TOH is a valid and reliable experimental paradigm that can be used to assess rule application, problem solving and transfer ( Huyck & Kreivenas, 2018 ; Schiff & Vakil, 2015 ). Rule application is demonstrated by the problem solver in the TOH by configuring the disks and the rods to reach a solution in the problem space. By configuring the disks on to the rods, each move of a disk indicates the problem solver attempting to creatively apply the rules. Participants played the TOH on a computer from a free website online. The test score (i.e., lower scores are better) for completing the TOH can range anywhere from 31 (which is the minimal number of moves to execute) until it is solved.

PISA Problem Solving Test

The second external problem-solving measure in this study is the (2003) version of the PISA Problem Solving Test. The PISA Problem Solving Test ( OECD, 2003 ) contains 10 novel problem-solving scenarios, and within each scenario there is a range of one to three different questions that must be solved. There are 19 total questions on the test across all scenarios that required students to solve problems. For this study, participants completed five novel problem-solving scenarios for the pretest and the remaining five novel problem-solving scenarios for the posttest. The levels of proficiency for each question are randomized across all problem-solving scenarios. Each problem-solving scenario is independent from one another and each of the 19 questions across all scenarios being assessed in this study are isomorphic from the questions that were implemented in 2003. The scoring for most questions was either correct or incorrect, with some questions allowing for partially correct answers. Participants that answered each question correctly were awarded one point, while partially correct answers awarded participants a half-point.

Participants for this study were recruited via flyers posted publicly on campus and dormitory bulletin boards. Over the course of eight weeks, participants engaged in 10 gameplay sessions that lasted two hours each. Participants had the opportunity to complete these 10 sessions in two-hour time-blocks that were made available Monday through Friday for eight consecutive weeks. Participants completed the experiment in a classroom lab on campus at the university. In this experiment, student participants were randomly assigned to play one of two video games.

Participants in the experimental condition played the popular roleplaying video game Warcraft that promotes learning new terminologies, mastering interrelated skills and abilities, applying rules to solve problems, goal setting, and reflecting on progress. In addition, participants in the active control condition played the brain-training video game CogniFit (2019) . The video game allows players to select various mini-games including Gem Breaker 3D that may enhance cognitive abilities including rule application, memory, and focus. Student participants in this study were guided by discovery learning and provided with in-game tutorials for each condition while learning to solve problems through active exploration, interacting with the game environment and self-direction ( Westera, 2019 ). At pre-test and post-test participants had 20 minutes to complete isomorphic versions of the TOH as many times as possible. All participants successfully completed the TOH once during the pretest and once during the posttest. At pre-test and post-test, participants also had 20 minutes to complete as many questions as possible on The PISA Problem Solving Test. The pretest required participants to answer nine questions and the posttest required participants to answer 10 questions from multiple problem-based scenarios. Each problem-based scenario was unique, and some examples included the following: (1) calculating the distance between two points given a map; (2) developing a decision tree diagram of a library loan system; and (3) calculating daily energy needs for an individual given a set menu.

Data Structure and Analyses

The full dataset used for all analyses to be presented, contained data from 34 participants. All participants attempted three parallel, computerized forms of the TOH at baseline and at the end of the intervention. Due to the nature of the task’s programming, if participants did not complete a TOH task, the total number of moves attempted was not output to the data file. This will be expanded upon in the results section by utilizing three analyses which included an independent t-test comparing the mean number of incomplete TOH games between the groups, an independent t-test comparing the mean gain score of TOH between the groups, and a multiple linear regression predicting max gain score of TOH by group, by gain score count, and by group, gain score count, and PISA gain. All analyses in sections below were completed in R, version 3.4.3. Packages used for data analysis include: dplyr , for data wrangling ( Wickham et al., 2019 ), and ggplot2 for visualizations ( Wickham, 2016 ), and MASS for stepwise regression analyses ( Venables & Ripley, 2002 ).

Assessing Group differences in Completion

Although groups differed on the overall number of incomplete TOH sessions at pre-testing (N COGNITIVE = 13; N GAMING = 8), an independent t-test of the average number of incomplete games by group, was not significant (p > .05). Furthermore, an independent t-test revealed no group differences for the overall number of incomplete TOH sessions at post-testing (N COGNITIVE = 3; N GAMING = 2; p > .05). A repeated-measures ANOVA revealed a significant time effect, F(1,32) = 13.386, p<.001. However, group, F(1,32) = 1.609, p=.214, nor group by time interaction were significant, F(1,32)=.837, p=.367. On average, participants completed an additional half TOH session (i.e., .47, SD = .53) after receiving either training package (M Pre = .62, SD = .70; M Post = .15, SD = .36). Table 3 shows the means and standard deviations for the pretest and posttest scores participants completed in the experimental ( Warcraft ) and control ( CogniFit ) groups. The mean scores in the table indicate how many moves on average each participant could successfully solve the puzzle per group. For this study, participants had 20 minutes to complete as many questions as possible for the pretest and 20 minutes to do the same for an isomorphic version of the posttest. Table 4 shows the means and standard deviations for the PISA pretest and posttest scores of participants in the experimental ( Warcraft ) and control ( CogniFit ) groups.

Pretest and posttest scores by group on the Tower of Hanoi

Pretest and posttest scores by group on the PISA Problem Solving Test

Quantifying Improvement in Performance

In order to quantify improvement after the intervention, gain scores were calculated by the following formula, for each instance of the TOH task encountered (i.e. three sessions):

Gain scores produced from this calculation can be interpreted as follows: negative gain scores indicating improvement (fewer total moves at post-testing), and positive gain scores indicating a decrement in performance (more total moves at post-testing). As a result of incomplete games not producing the number of moves, for some participants, no gain score calculation was possible. At pretesting, the cognitive training group had three missing gain scores for the second TOH and 10 for the third TOH whereas the game training group had one missing gain score for the second TOH and seven for the third TOH. To account for this, when calculating average gain scores for each participant, averages were weighted by the number of completed games (i.e. averaging by the number of incomplete sessions would result in an undefined calculation, as some participants completed all sessions). Table 5 shows the results of an unpaired t-test on the average weighted gain scores found no group differences in TOH gain scores ( p > .05). Additionally, an unpaired t-test on the average PISA gain scores found no group differences gain scores ( p > .05).

Problem solving performance compared across training groups

Sensitivity Analysis

Due to missing data issues discussed above, the final analysis involves a stepwise multiple linear regression (forward and backward; AIC used for final model variable selection conducted using R package MASS, function stepAIC; Venables & Ripley, 2002 ), predicting max gain score (max of all three potential gain scores) by group membership (WoW or Cognitive Training), total gain score count, and a gain score derived from pre and post measurements on the PISA task (2003). Based on the stepwise regression procedure analysis results in Table 6 , the best fitting, significant, multiple regression model was found to be a model predicting max gain score from gain score count (no predictor for group membership or PISA gain score; F(1,32) = 14.41; p < .001; R 2 = .3104; adjusted R 2 = 0.2889). Participants predicted max gain score is equal to −111.70 + 48.87 (Gain Count), where gain score is in the unit of number of moves. Max gain score increased by 48.87 for every one unit increase in gain score count (more gain scores, closer to 0; less improvement after the intervention). Gain score count was a significant predictor of max gain score (t=3.796; p < 0.001), indicating potential practice effects from repeated exposure to the task. Practice effects will be discussed in subsequent sections.

Stepwise regression model path, analysis of deviance table and the row with the best fitting model, using AIC as criterion, is highlighted in gray

Evidence for Research Question 1

The initial hypothesis regarding the first question was that a brain-training game would help participants improve their rule application component of problem-solving skill better than a roleplaying game after 20 hours of gameplay for several reasons. One reason is that the rules are more explicit during brain-training gameplay and because of claims made by CogniFit that brain-training gameplay will improve its users’ brain fitness or ability to rely on more than one problem-solving strategy. While both games require players to apply rules to solve problems, only CogniFit markets its product as a tool that can help users to solve problems in their daily lives ( CogniFit, 2019 ). This claim also suggests that brain-training gameplay can help users transfer skills learned in-game to novel problem-solving scenarios in the natural world. However, the results indicated that there was no significant difference in gain scores (i.e., in Post - Pre Gain scores) in terms of TOH performance (t-test comparing gain scores: p = .746) between the two gaming conditions (i.e., Warcraft and CogniFit ), though both groups improved from baseline to post-testing assessment, likely attributable to practice effects (see Figure 5 ). Overall, the results contradicted our initial hypothesis for Research Question 1; implications are discussed next.

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Average number of moves in the Tower of Hanoi task across (up to 3) sessions per person, per timepoint. The left panel represents scores for the CogniFit (COG) group, and the right panel represents scores for the Warcraft (WOW) group.

Implications of Results for Research Question 1

Solving problems in an immersive game like Warcraft provided players with repeated practice of applying rules and using tools to find creative solutions to similar but varied problems. As players reflected on their choices, they learned how to use the tools by analyzing givens and constraints in unison to achieve maximum character performance and develop optimal solutions to general problems. CogniFit players did not experience immersive gameplay, but instead repeated problem-solving scenarios that were varied but required fewer tools and resources to be solved. Once CogniFit players knew how to use the paddle and the ball in unison, the only additional resources to use during gameplay were power-ups, bonus bricks, and traps. Roleplaying gameplay required players to solve problems using additional tools and resources efficiently which was a more complex task than using the ball and paddle during brain-training gameplay. Strategizing when and how to apply rules through varied but different problem scenarios with multiple tools and resources through immersive gameplay was beneficial for Warcraft participants. Moreover, players in Warcraft could receive feedback with help from other players learning when and how to apply tools and resources to solve problems. CogniFit players received feedback at the end of each level with an overall score and corrected mistakes through trial and error without additional support.

evidence for Research Question 2

The initial hypothesis regarding the second question was that training on an immersive, collaborative roleplaying video game for 20 hours would engender transfer of problem-solving skills to novel problem-solving scenarios on the PISA Problem Solving Test better than a brain-training video game. One reason is that research on MMORPGs including Warcraft indicates that players co-constructed knowledge by challenging and supporting novel ideas to in-game problem-solving scenarios through online discussion forums as well as discovering optimal solutions to in-game problems by combining multiple abilities and resources available to players ( Chinn & Malhotra, 2002 ; Steinkuehler & Chmiel, 2006 ). Efficiently using tools and resources is a component of problem solving and is central to the roleplaying gameplay experience ( Shute & Wang, 2016 ).

However, the results indicated that after 20 hours of gameplay of Warcraft or CogniFit there was no improved performance on the PISA (i.e., comparing PISA Gain Scores; p = .748). Overall, the mean scores for Warcraft participants were slightly better than CogniFit participants on the isomorphic versions of the PISA Problem Solving pretest and posttest - indicating baseline differences between the two groups in terms of performance. Overall, there were no significant differences found between roleplaying and brain-training gameplay on transfer of problem-solving skills (see Figure 6 ). The implications for the results from research question 2 are discussed next.

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PISA Scores before and after the intervention. The left panel represents scores for the COG group, and the right panel represents scores for the WOW group.

Implications of Results for Research Question 2

Given that both video game training and “brain-training” did not significantly improve problem-solving skills has several implications. The gameplay behaviors exhibited by players in each condition were aligned with the problem-solving processes on the PISA Problem Solving Test. However, possible reasons for lack of transfer in this study in addition to small sample size include (a) collaborative, immersive roleplaying gameplay may help promote problem-solving skills related to in-game problem solving scenarios but not necessarily to improved performance on external problem-solving assessments, and (b) problem-solving during Warcraft gameplay may be too domain specific to transfer to novel problem-solving scenarios on the PISA Problem Solving Test.

The misalignment between the problem-solving domains of Warcraft and the PISA Problem Solving Test could have hindered the possibility of finding a transfer effect. As an example, Warcraft players must learn how to navigate an immersive environment, use complex tools efficiently and effectively to solve problems during gameplay and interact with both the environment and other characters to solve problems. However, solving problems on the PISA Problem Solving Test is not an immersive experience. It was also a solitary activity; participants did not collaborate or interact with each other while taking the test. The OECD designed the PISA Problem Solving Test to cover more general problem-solving skills to complement domain-specific skills ( Greiff et al., 2014 ). Selecting a problem-solving assessment which is embedded within an immersive environment that requires players to engage in collaborative problem-solving processes (i.e. experienced in video gameplay) using tools and resources efficiently could have been a more viable assessment to measure transfer of problem-solving skills in this study. Further research is still warranted to determine if video gameplay can promote transfer of problem-solving skills to novel scenarios. The limitations of this research study are addressed in the next section.

Limitations

Given time and resource constraints, the sample size of this study is small and lacks statistical significance to make claims regarding the general population. With more available resources, recruitment would have likely continued for an additional semester to raise the sample size for the study. Students that did not complete the study cited time constraints as the main reason they were unable to fulfill the 20 hours of video gameplay requirement. The optimal time to run the study would have been during Fall and Spring semesters instead of Spring and Summer. In Fall and Spring, more students would have been available for recruitment as well as increased scheduling flexibility and time to complete the intervention during the academic year for the participants. Given that the authors monitored participants during video gameplay in case any problems arose, there may have been expectancy effects that impacted participants. For example, participants’ gameplay experiences may have been negatively or positively affected when being monitored. The potential for participants to alter their behavior simply because they are being studied is known as the Hawthorne Effect ( Benedetti, Carlino & Piedimonte, 2016 ). In addition, the inclusion of a more immersive assessment that measures problem-solving skill transfer could have led to improved outcomes when compared to a more traditional assessment like the PISA Problem-Solving Test (2003).

Future Implications

The main goal of this study was to examine the impact of two distinct types of video gameplay; role playing ( Warcraft ) and brain-training ( CogniFit ) on problem-solving skills for undergraduates. Specifically, if video gameplay can improve the rule application component of problem solving and whether problem solving during gameplay transferred to novel problem-solving scenarios. This study addressed some of the methodological shortcomings found in previous video game training and transfer studies that failed to report recruitment methods, define study variables, and provide an active control group in which participants could expect receive equal improvement from competencies ( Baniqued et al., 2013 ; Boot et al., 2013 ). As a result, possible placebo effects are likely mitigated in this experiment improving upon methodological pitfalls affecting other video game training studies ( Anderson et al., 2010 ; Ferguson & Kilburn, 2009 ).

The results from this study suggest that neither a commercially available video game ( Warcraft ) or a commercially available “brain-training” package ( CogniFit ) resulted in improvements in the rule-based component of problem solving (as assessed by the TOH puzzle). Moreover, aside from a lack of improvement in the rule-based component, 20-hours of training did not promote transfer of problem-solving skills to novel scenarios (as assessed by the PISA Problem Solving Task), which is consistent with similar research findings on cognitive training and transfer ( Souders et al., 2017 ). Sensitivity analyses conducted found evidence for practice effects in gain scores, illustrating that rather than improvement due to the training packages, improvement seems related to multiple, closely spaced assessments. Future research can complement this study by increasing the sample size and testing similar immersive well-designed video games on participant knowledge, skills, and abilities, in addition to directly cuing participants to be aware of the strategies (i.e., perceptual and cognitive strategies) they might carry with them from the digital world to the real-world.

Acknowledgment

Nelson Roque was supported by National Institute on Aging Grant T32 AG049676 to The Pennsylvania State University.

Benjamin Emihovich is an Assistant Professor of Educational Technology in the Education Department at the University of Michigan-Flint and is the program faculty coordinator for the online Educational Technology (M.A.) program. He currently teaches undergraduate and graduate students in the areas of Instructional Design and Technology as well as curriculum and instruction. His research area focuses on the following; game-based learning, assessments for learning in immersive environments, and emerging learning technologies.

Nelson A. Roque is a NIA T32 Postdoctoral Fellow, at Penn State’s Center for Healthy Aging. Nelson earned his Ph.D. in Cognitive Psychology from Florida State University in 2018. Nelson has a strong background in visual attention, focusing on how to reliably measure it, how it relates to individual difference factors (e.g., age, sleep) and translating insights from theoretical work in visual attention to applied contexts (e.g. medication errors).

Justin Mason is a Postdoctoral Associate in Rehabilitation Science at the University of Florida. His research interests include interventions suitable for mitigating age-related cognitive and physical decline in older adults. Additionally, he’s interested in factors that influence older adults’ adoption and acceptance of emerging technologies.

Contributor Information

Benjamin Emihovich, University of Michigan - Flint, Flint, USA.

Nelson Roque, Pennsylvania State University, State College, USA.

Justin Mason, University of Florida, Gainesville, USA.

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7 Problem Solving Skills That Aren’t Just Buzzwords (+ Resume Example)

Julia Mlcuchova ,
Updated April 8, 2024 9 min read

Problem-solving skills are something everybody should include on their resume, yet only a few seem to understand what these skills actually are. If you've always felt that the term "problem-solving skills" is rather vague and wanted to know more, you've come to the right place.

In this article, we're going to explain what problem-solving skills really mean. We'll talk about what makes up good problem-solving skills and give you tips on how to get better at them. You'll also find out how to make your problem-solving abilities look more impressive to those who might want to hire you.

Sounds good, right? Curious to learn more?

In this article we’ll show you:

What are problem solving skills;
Why are they important;
Specific problem solving skills examples;
How to develop your problem solving skills;
And, how to showcase them on your resume.

Click on a section to skip

What are problem solving skills?

Why are problem solving skills important, the best 7 problem solving skills examples, how to develop problem solving skills, problem solving skills resume example, key takeaways: problem solving skills.

First of all, they're more than just a buzzword!

Problem-solving skills are a set of specific abilities that allow you to deal with unexpected situations in the workplace, whether it be job related or team related.

It's a complex process that involves several “sub skills” or “sub steps,” namely:

Recognizing and identifying the issue at hand.
Breaking the problem down into smaller parts and analyzing how they relate to one another.
Creating potential solutions to the problem, evaluating them and picking the best one.
Applying the chosen solution and assessing its outcome.
Learning from the whole process to deal with future problems more effectively.

As you can see, it's not just about solving problems that are right in front of us, but also about predicting potential issues and being prepared to deal with them before they arise.

Despite what you may believe, problem-solving skills aren't just for managers .

Think about it this way: Why do employers hire employees in the first place? To solve problems for them!

And, as we all know, problems don't discriminate. In other words, it doesn't matter whether you're just an intern, an entry-level professional, or a seasoned veteran, you'll constantly face some kind of challenges. And the only difference is in how complex they will get.

This is also reflected in the way employers assess suitability of potential job candidates.

In fact, research shows that the ability to deal with unexpected complications is prioritized by an overwhelming 60% of employers across all industries, making it one of the most compelling skills on your resume.

So, regardless of your job description or your career level, you're always expected to find solutions for problems, either independently or as a part of a team.

And that's precisely what makes problem-solving skills so invaluable and universal !

Wondering how good is your resume?

Find out with our AI Resume Checker! Just upload your resume and see what can be improved.

As we've said before, problem-solving isn't really just one single skill.

Instead, your ability to handle workplace issues with composure depends on several different “sub-skills”.

So, which specific skills make an employee desirable even for the most demanding of recruiters?

In no particular order, you should focus on these 7 skills :

Analytical skills
Research skills
Critical thinking
Decision-making
Collaboration
Having a growth mindset

Let's have a look at each of them in greater detail!

#1 Analytical skills

Firstly, to truly understand complex problems, you need to break them down into more manageable parts . Then, you observe them closely and ask yourself: “ Which parts work and which don't,” How do these parts contribute to the problem as a whole,” and "What exactly needs to be fixed?” In other words, you gather data , you study it, and compare it - all to pinpoint the cause of the issue as closely as possible.

#2 Research skills

Another priceless tool is your research skills (sometimes relying on just one source of information isn't enough). Besides, to make a truly informed decision , you'll have to dig a little deeper. Being a good researcher means looking for potential solutions to a problem in a wider context. For example: going through team reports, customer feedback, quarterly sales or current market trends.

#3 Critical thinking

Every employer wants to hire people who can think critically. Yet, the ability to evaluate situations objectively and from different perspectives , is actually pretty hard to come by. But as long as you stay open-minded, inquisitive, and with a healthy dose of skepticism, you'll be able to assess situations based on facts and evidence more successfully. Plus, critical thinking comes in especially handy when you need to examine your own actions and processes.

#4 Creativity

Instead of following the old established processes that don't work anymore, you should feel comfortable thinking outside the box. The thing is, problems have a nasty habit of popping up unexpectedly and rapidly. And sometimes, you have to get creative in order to solve them fast. Especially those that have no precedence. But this requires a blend of intuition, industry knowledge, and quick thinking - a truly rare combination.

#5 Decision-making

The analysis, research, and brainstorming are done. Now, you need to look at the possible solutions, and make the final decision (informed, of course). And not only that, you also have to stand by it ! Because once the train gets moving, there's no room for second guessing. Also, keep in mind that you need to be prepared to take responsibility for all decisions you make. That's no small feat!

#6 Collaboration

Not every problem you encounter can be solved by yourself alone. And this is especially true when it comes to complex projects. So, being able to actively listen to your colleagues, take their ideas into account, and being respectful of their opinions enables you to solve problems together. Because every individual can offer a unique perspective and skill set. Yes, democracy is hard, but at the end of the day, it's teamwork that makes the corporate world go round.

#7 Having a growth mindset

Let's be honest, no one wants their work to be riddled with problems. But facing constant challenges and changes is inevitable. And that can be scary! However, when you're able to see these situations as opportunities to grow instead of issues that hold you back, your problem solving skills reach new heights. And the employers know that too!

Now that we've shown you the value problem-solving skills can add to your resume, let's ask the all-important question: “How can I learn them?”

Well…you can't. At least not in the traditional sense of the word.

Let us explain: Since problem-solving skills fall under the umbrella of soft skills , they can't be taught through formal education, unlike computer skills for example. There's no university course that you can take and graduate as a professional problem solver.

But, just like other interpersonal skills, they can be nurtured and refined over time through practice and experience.

Unfortunately, there's no one-size-fits-all approach, but the following tips can offer you inspiration on how to improve your problem solving skills:

Cultivate a growth mindset. Remember what we've said before? Your attitude towards obstacles is the first step to unlocking your problem-solving potential.
Gain further knowledge in your specialized field. Secondly, it's a good idea to delve a little deeper into your chosen profession. Because the more you read on a subject, the easier it becomes to spot certain patterns and relations.
Start with small steps. Don't attack the big questions straight away — you'll only set yourself up for failure. Instead, start with more straightforward tasks and work your way up to more complex problems.
Break problems down into more digestible pieces. Complex issues are made up of smaller problems. And those can be further divided into even smaller problems, and so on. Until you're left with only the basics.
Don't settle for a single solution. Instead, keep on exploring other possible answers.
Accept failure as a part of the learning process. Finally, don't let your failures discourage you. After all, you're bound to misstep a couple of times before you find your footing. Just keep on practicing.

How to improve problem solving skills with online courses

While it’s true that formal education won’t turn you into a master problem solver, you can still hone your skills with courses and certifications offered by online learning platforms :

Analytical skills. You can sharpen your analytical skills with Data Analytics Basics for Everyone from IBM provided by edX (Free); or Decision Making and Analytical Thinking: Fortune 500 provided by Udemy (＄21,74).
Creativity. And, to unlock your inner creative mind, you can try Creative Thinking: Techniques and Tools for Success from the Imperial College London provided by Coursera (Free).
Critical thinking. Try Introduction to Logic and Critical Thinking Specialization from Duke University provided by Coursera (Free); or Logical and Critical Thinking offered by The University of Auckland via FutureLearn.
Decision-making. Or, you can learn how to become more confident when it's time to make a decision with Decision-Making Strategies and Executive Decision-Making both offered by LinkedIn Learning (1 month free trial).
Communication skills . Lastly, to improve your collaborative skills, check out Communicating for Influence and Impact online at University of Cambridge.

The fact that everybody and their grandmothers put “ problem-solving skills ” on their CVs has turned the phrase into a cliche.

But there's a way to incorporate these skills into your resume without sounding pretentious and empty. Below, we've prepared a mock-up resume that manages to do just that.

FYI, if you like this design, you can use the template to create your very own resume. Just click the red button and fill in your information (or let the AI do it for you).

Problem solving skills on resume example

This resume was written by our experienced resume writers specifically for this profession.

Why this example works?

Firstly, the job description itself is neatly organized into bullet points .
Instead of simply listing soft skills in a skills section , you can incorporate them into the description of your work experience entry.
Also, the language here isn't vague . This resume puts each problem-solving skill into a real-life context by detailing specific situations and obstacles.
And, to highlight the impact of each skill on your previous job position, we recommend quantifying your results whenever possible.
Finally, starting each bullet point with an action verb (in bold) makes you look more dynamic and proactive.

To sum it all up, problem-solving skills continue gaining popularity among employers and employees alike. And for a good reason!

Because of them, you can overcome any obstacles that stand in the way of your professional life more efficiently and systematically.

In essence, problem-solving skills refer to the ability to recognize a challenge, identify its root cause, think of possible solutions , and then implement the most effective one.

Believing that these skills are all the same would be a serious misconception. In reality, this term encompasses a variety of different abilities , including:

In short, understanding, developing, and showcasing these skills, can greatly boost your chances at getting noticed by the hiring managers. So, don't hesitate and start working on your problem-solving skills right now!

Julia has recently joined Kickresume as a career writer. From helping people with their English to get admitted to the uni of their dreams to advising them on how to succeed in the job market. It would seem that her career is on a steadfast trajectory. Julia holds a degree in Anglophone studies from Metropolitan University in Prague, where she also resides. Apart from creative writing and languages, she takes a keen interest in literature and theatre.

How many bullet points per job on resume spoiler: there is an ideal number, best resume advice according to reddit: 6 tips that actually work, share this article, join our newsletter.

Every month, we’ll send you resume advice, job search tips, career hacks and more in pithy, bite-sized chunks. Sounds good?

ORIGINAL RESEARCH article

Integrating inquiry and mathematical modeling when teaching a common topic in lower secondary school: an istem approach provisionally accepted.

1 Hong Kong Baptist University, Hong Kong, SAR China

The final, formatted version of the article will be published soon.

The world has been increasingly shaped by Science, Technology, Engineering and Mathematics (STEM). This has resulted in educational systems across the globe implementing STEM education. To reap maximum benefits, researchers are now advocating for the integration of STEM domains. In recent studies, the integration of science and mathematics has become increasingly popular. The domains are much more suitable for integration because of their fields of application and their mutual approach towards problem-solving. However, there is little empirical evidence to drive the development of a practical model for classroom implementation. This study aims to cover that gap through integrating mathematics and science concepts when teaching a common topic to two classes of Form 1 (13-14 years) students. A mathematics and a science teacher went through two cycles of lesson study, integrating and teaching the concept of density. Results show a strong synergy between the BSCS 5E instructional model of inquiry and mathematical modeling; hence the methodological approaches can be used to integrate common topics like density. Further, teacher collaboration, teacher immersion in the iSTEM practices, teacher's knowledge, and skills of the other subject and an in-depth understanding of a problem and its contextualization, are variables that can be capitalized on to enhance the teacher's capacity to implement innovative and integrated STEM programs effectively.

Keywords: iSTEM1, Inquiry2, mathematical modeling3, Integration model4, Science5. Mathematics6, Density7

Received: 26 Jan 2024; Accepted: 10 Apr 2024.

Copyright: © 2024 Manunure and Leung. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY) . The use, distribution or reproduction in other forums is permitted, provided the original author(s) or licensor are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

* Correspondence: Mr. Kevin Manunure, Hong Kong Baptist University, Kowloon, Hong Kong, SAR China

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Want To Make More Money at Work? Improve These 8 Skills

E mployers love a capable employee. Adding certain skills to your repertoire can boost your value to your company and make you more competitive in future job searches. Some skills, however, are more likely than others to also lead to better and higher pay .

For You: 26 Ways To Make $1,000 Fast — In a Week or Less

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Leadership skills are among the most coveted among employers. Scott Lieberman, HR expert and founder of Touchdown Money , said, “Showing that you have a strong work ethic, can effectively manage others, can problem solve and are willing to get the job done will increase your chances of gaining promotions and increasing your pay.”

Explore More: 6 Best ChatGPT Prompts To Find Your High-Income Side Gig

Technical Know-How

In this digital age, where AI is transforming many of the ways people work, Lieberman pointed out, “Choosing to consistently learn new technologies, upgrade your education about your profession and implement those skills shows your willingness to be a top performer.”

In a similar vein, Abid Salahi, co-founder of FinlyWealth , suggested that becoming a “data driven dynamo” can work in your favor.

“The world runs on data. Companies crave employees who can wrangle, analyze and interpret this valuable information,” Salahi explained.

Mastering software or hardware — or both — can make you a highly sought-after asset. Salahi said that data science jobs command an average base salary of over $120,000 in the U.S. as of 2023.

Communication

There may truly be no skill more essential than good communication. Being able to convey your thoughts and ideas clearly, effectively collaborate with team members and listen shows your respect for coworkers, Lieberman explained.

Salahi added that being able to articulate ideas clearly, confidently present information and negotiate effectively can put you at the forefront regarding promotions and raises, too.

“A study by the American Marketing Association found that strong communication skills can increase your earning potential by up to 20%,” he said.

Reliability

Showing yourself as a reliable employee will definitely get noticed. Proving you can always get a task done on time or before a deadline shows you can consistently meet the expectations and requirements of your job, Lieberman said. “Employers want employees they can count on.”

Adaptability

Employees who can adapt to a constantly evolving work environment have a better chance at seeing higher pay, Salahi said. “Companies need employees who can learn new skills quickly and adapt to changing circumstances. Whether mastering new software or new workflows, agility keeps you relevant and valuable, often leading to more opportunities and higher salaries.”

Problem Solving

Don’t underestimate the power of good problem solving. Businesses face challenges daily, and those who can identify, analyze and solve problems effectively are invaluable, Salahi said.

“Develop your critical thinking skills and hone your ability to find creative solutions. Problem solvers are seen as future leaders, often commanding higher salaries and attracting promotions.”

Negotiation

Negotiating isn’t just for pay raises, according to Rhett Stubbendeck, CEO of LeverageRX . “At Leverage, I’ve used it to get better deals with our partners and suppliers. There was this one time I managed to cut a deal with a software provider that saved us 20% each year. It was a big win for us, and it showed me how valuable being a good negotiator can be.”

Adam Garcia, a finance and investing expert and owner of The Stock Dork , suggested those who have the brain for analytics will do especially well — and probably make better money, too.

“Skills that directly contribute to your job’s core functions and deliver measurable results, like financial analysis, data analysis, investment management, strategic planning and strong communication, can increase your earning potential at work in finance,” he said.

While these skills do make you more valuable to your employer, thus potentially increasing your pay, they also make you more marketable in general, if you’re ever back on the job market.

IMAGES

Developing Problem-Solving Skills for Kids
Problem-Solving Strategies: Definition and 5 Techniques to Try
7 Steps to Improve Your Problem Solving Skills
15 Ways to Learn How to Improve Problem Solving Skills
How to Improve Children’s Problem Solving Skills
15 Ways to Learn How to Improve Problem Solving Skills

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Problem Solving Techniques
How to improve problem solving skills #problem
IMPROVE PROBLEM SOLVING SKILLS WITH DESIGN THINKING
How to IMPROVE your Problem-Solving Skills, Guide 2024. #shortsfeed #desarrollopersonal #SHORT

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4 Strategies to Build Your Students' Problem Solving Skills
Enhances Creativity and Critical Thinking: Problem-solving activities often require students to think outside the box and use their critical thinking abilities. This stimulates creativity and fosters innovative thought. Boosts Confidence: As students improve their problem-solving abilities, they gain confidence in their skills. This confidence ...
Strategies To Develop Problem-Solving Skills In Students
Another strategy to encourage the development of problem-solving skills in students is to allow for plenty of discussion and collaboration in the classroom setting. When students interact with one another, they are naturally developing problem solving skills. Rather than the teacher delivering information and requiring the students to passively ...
Building Students' Problem-Solving Skills
Our approach includes cooperative games and design challenges as well as good-to-know and problem jars. Each part is designed to allow our students to encounter consistent developmentally appropriate and varying types of conflict in order to build problem-solving skills. Throughout each activity, students are put in a variety of mixed groupings ...
Strengthening High School Students' Problem-Solving Skills
Finding, shaping, and solving problems puts high school students in charge of their learning and bolsters critical-thinking skills. As an educator for over 20 years, I've heard a lot about critical thinking, problem-solving, and inquiry and how they foster student engagement. However, I've also seen students draw a blank when they're ...
Developing Problem-Solving Skills for Kids
Problem-Solving Skills for Kids: Student Strategies. These are strategies your students can use during independent work time to become creative problem solvers. 1. Go Step-By-Step Through The Problem-Solving Sequence. Post problem-solving anchor charts and references on your classroom wall or pin them to your Google Classroom - anything to make ...
3 Ways to Improve Student Problem-Solving
3 Ways to Improve Student Problem-Solving. 1. Slow reveal graphs: The brilliant strategy crafted by K-8 math specialist Jenna Laib and her colleagues provides teachers with an opportunity to gradually display complex graphical information and build students' questioning, sense-making, and evaluating predictions.
Strategies and Methods to Teach Students Problem Solving and Critical
The process helps participants to view implementation as a viable next step. Thinking Skills. Skills aimed at aiding students to be critical, logical, and evaluative thinkers. They include analysis, comparison, classification, synthesis, generalization, discrimination, inference, planning, predicting, and identifying cause-effect relationships.
Don't Just Tell Students to Solve Problems. Teach Them How
The University of California San Diego Jacobs School of Engineering is on the forefront of efforts to improve how problem solving is taught. This UC San Diego approach puts hands-on problem-identification and problem-solving techniques front and center. Over 1,500 students across the San Diego region have already benefited over the last three ...
Teaching Problem Solving
Make students articulate their problem solving process . In a one-on-one tutoring session, ask the student to work his/her problem out loud. This slows down the thinking process, making it more accurate and allowing you to access understanding. When working with larger groups you can ask students to provide a written "two-column solution.".
Tweak your questions to improve students' problem-solving skills
In a new study, researchers examined how the presentation and format of practice questions influences students' problem-solving performance. The study revealed that mixed problem sets are better than questions arranged by topic. There are two types of question practice teachers can give their students. The first, blocked practice, involves ...
Why Every Educator Needs to Teach Problem-Solving Skills
Problem-solving skills are also needed for students' personal growth and development because they help individuals overcome obstacles and achieve their goals. By developing strong problem-solving skills, students can improve their overall quality of life and become more successful in their personal and professional endeavors.
12 Ways to Improve Problem Solving Skills
On the other hand, you might try to save by cutting your spending or by lowering other costs. Use some strategies to help you come up with solutions: Divide and conquer. Break the problem into smaller problems and brainstorm solutions for them separately, one by one. Use analogies and similarities.
3 Ways to Improve Your Students' Problem-Solving Skills
Way 3: Provide opportunities for students to engage in structured discourse. Problem-solving is often thought of as an isolated topic in math classes. Some might even imagine it to look like students working independently. When presented with a problem in the real world, we often seek others' help.
How to Develop Problem Solving Skills: 4 Tips
1. Creativity: Effective problem solving requires the ability to brainstorm solutions and think outside the box to arrive at new approaches to longstanding problems. 2. Teamwork: Addressing a group problem or systemic social problem requires you to work collaboratively and supportively with other team members. 3.
How to Help Your Students Improve Their Problem-Solving Skills
The second step is to teach your students a systematic process for problem-solving. There are many models and frameworks you can use, such as the Polya method, the IDEAL model, or the CPS process.
How to improve your problem solving skills and strategies
6. Solution implementation. This is what we were waiting for! All problem solving strategies have the end goal of implementing a solution and solving a problem in mind. Remember that in order for any solution to be successful, you need to help your group through all of the previous problem solving steps thoughtfully.
How to Improve Your Problem-Solving Skills
1. IDENTIFY the problem. In a nutshell, my definition of problem-solving skills is very simple: it is the ability to identify the nature of a problem, deconstruct it (break it down) and develop an effective set of actions to address the challenges related to it. Indeed, in some challenging situations many students are overwhelmed with emotions ...
The effectiveness of collaborative problem solving in promoting
Duch et al. noted that problem-based learning in group collaboration is progressive active learning, which can improve students' critical thinking and problem-solving skills.
Helping Students Hone Their Critical Thinking Skills
Teach Reasoning Skills. Reasoning skills are another key component of critical thinking, involving the abilities to think logically, evaluate evidence, identify assumptions, and analyze arguments. Students who learn how to use reasoning skills will be better equipped to make informed decisions, form and defend opinions, and solve problems.
How to Measure Problem-Solving Skills and Student Outcomes
Use valid and reliable tools. 4. Compare and contrast results. 5. Communicate and apply findings. 6. Here's what else to consider. Be the first to add your personal experience. Problem-solving ...
7 Problem-Solving Skills That Can Help You Be a More ...
Although problem-solving is a skill in its own right, a subset of seven skills can help make the process of problem-solving easier. These include analysis, communication, emotional intelligence, resilience, creativity, adaptability, and teamwork. 1. Analysis. As a manager, you'll solve each problem by assessing the situation first.
(PDF) Improving student problem-solving skill and cognitive learning
This study aimed to improve student problem-solving skill and cognitive learning outcome through the implementation of problem-based learning (PBL) model in learning biology at the senior high school.
How to Improve Your Teaching with Problem-Solving Skills
Learn about four problem-solving skills that can help you cope with teaching challenges and improve your student outcomes. Find out how to define, generate, evaluate, and implement solutions.
Can Video Gameplay Improve Undergraduates' Problem-Solving Skills?
Future Implications. The main goal of this study was to examine the impact of two distinct types of video gameplay; role playing ( Warcraft) and brain-training ( CogniFit) on problem-solving skills for undergraduates. Specifically, if video gameplay can improve the rule application component of problem solving and whether problem solving during ...
7 Problem Solving Skills That Aren't Just Buzzwords (+ Examples)
The best 7 problem solving skills examples. As we've said before, problem-solving isn't really just one single skill.. Instead, your ability to handle workplace issues with composure depends on several different "sub-skills".
Frontiers
Further, teacher collaboration, teacher immersion in the iSTEM practices, teacher's knowledge, and skills of the other subject and an in-depth understanding of a problem and its contextualization, are variables that can be capitalized on to enhance the teacher's capacity to implement innovative and integrated STEM programs effectively.
Want To Make More Money at Work? Improve These 8 Skills
Problem Solving Don't underestimate the power of good problem solving. Businesses face challenges daily, and those who can identify, analyze and solve problems effectively are invaluable, Salahi ...

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What Are Problem-Solving Skills?

Importance of Problem-Solving in the Classroom Setting

Benefits of Problem-Solving Skills for Students

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Developing Confidence

Preparing Students for Real-World Challenges

The Best Problem-Solving Strategies for Students

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Encourage Discussion and Collaboration in the Classroom Setting

Utilising an Inquiry-Based approach to Learning

Model Appropriate Problem-Solving Skills

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Developing Problem-Solving Skills for Kids | Strategies & Tips

Problem-Solving Skills for Kids: The Real Deal

Problem-Solving Skills for Kids: Student Strategies

1. Go Step-By-Step Through The Problem-Solving Sequence

2. Revisit Past Problems

3. Document What Doesn’t Work

4. "3 Before Me"

Problem-Solving Skills for Kids: Teacher Tips

1. Ask Open Ended Questions

2. Encourage Grappling

3. Emphasize Process Over Product

4. Model The Strategies Yourself!

Problem-Solving Skill for Kids

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Don’t Just Tell Students to Solve Problems. Teach Them How.

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