phd program in quantum information

Top 20 Quantum Computing Masters & Ph.D. Degree Programs in 2024

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• June 6, 2022

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Because quantum computing requires a background in research, it’s important for those entering the quantum workforce to go through one of the many rigorous quantum computing Ph.D. or master’s programs.

There are many universities around the world offering quantum computing as a graduate program. Many of them have also spawned some of the biggest names in quantum computing, allowing a bridge to form between research and industry. This is especially beneficial for students looking to transition from academia into a quantum computing job .

While the choices of quantum computing degree programs seem nearly endless, we at Quantum Insider want to offer a summarized list of what we believe are a few of the top ones to get a Ph.D. or master’s in quantum computing. This is not at all exhausting as many universities continue to advance their quantum computing programs or work with companies to help enhance opportunities for their students.

We’ve organized a list of the top 20 quantum computing master’s and Ph.D. programs to get a degree in 2024. Enjoy!

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20 Quantum Computing Degree Programs

1. mit’s lincoln laboratory.

It’s no surprise that the top quantum computing graduate programs are hosted by some of the most prestigious schools. MIT is no exception, as its Lincoln Laboratory studies integrated nano-systems and quantum information. MIT’s masters in quantum computing focus on trapped-ion qubits as well as designing integrated quantum circuits. The laboratory offers several different projects to work on, all with real-world applications.

2. University of California Berkeley

UC Berkeley is one of the many universities in California looking into quantum computing , mimicking the hub of activity by quantum companies in that area. The Berkeley Lab works on harnessing quantum computing to help solve real-world issues. With research topics ranging from quantum materials to even training the quantum workforce, UC Berkeley’s quantum computing masters program offers a multi-disciplinary approach.

3. University of Chicago

The University of Chicago is one of the top quantum computing universities as it is home to the Chicago Quantum Exchange (CQE). The CQE connects other universities in the Midwest, as well as companies and other organizations to discuss developments in quantum technology. Because of the CQE, their quantum computing graduate students get exclusive networking opportunities and the ability to work on cutting-edge research.

4. University of Maryland’s Joint Quantum Institute (JQI)

The University of Maryland’s JQI offers a unique experience for students, as it includes quantum scientists from the National Institute of Standards and Technology (NIST), the University of Maryland, and the Laboratory for Physical Sciences (LPS). With this diversity in researchers, students have a wide range of quantum degree programs to choose from, including theoretical and experimental quantum physics.

5. University of Southern California’s Center for Quantum Information Science and Technology (CQIST)

Like UC Berkeley, USC’S CQIST focuses on quantum information science. However, its main focuses are on quantum computing, quantum cryptography, and quantum information theory. To research these subjects in their master’s and Ph.D. programs, CQIST brings in experts from both the school of Arts and Sciences and Engineering, giving all students an interdisciplinary focus on quantum computing technology.

6. California Institute of Technology (Caltech)

Studying quantum computing at Caltech, students become part of the university’s Institute for Quantum Information and Matter ( IQIM ). This institute is a National Science Foundation Physics Frontier Center , one of many government centers that encourage global collaboration and offer unique opportunities to quantum computing masters and Ph.D. students. These centers also work to give extra activities to enhance student education.

7. Stanford University

Stanford University has multiple researchers studying quantum computing, including the Q-Farm , an acronym standing for Quantum Fundamentals, Architectures, and Machine learning initiative. Q-Farm collaborates with Stanford’s National Acceleration Laboratory ( SLAC ) to develop answers to some of the biggest challenges for quantum computing.

8. Harvard University

Harvard University hosts the Harvard Quantum Initiative , which recently released a new quantum computing Ph.D. program in quantum science and engineering. The Harvard Quantum Initiative has a bustling hub of researchers focusing on properly training the next quantum workforce, while also working with industry partners to advance this technology. They offer a prize for Ph.D. researchers in quantum engineering as well as several summer research programs.

9. Carnegie Mellon University

The Pittsburgh Quantum Institute ( PQI ) at Carnegie Mellon University hosts over 100 members and workers to create a multidisciplinary quantum computing graduate program that involves engineering, business, philosophy of science, and other fields. PQI offers many opportunities to its quantum engineering students, including travel awards, poster sessions, public lectures, and outreach activities. The PQI also works closely with other centers, like the Pittsburgh Supercomputing Center, to work on this next-generation quantum technology.

10. University of Colorado Boulder

Within the University of Colorado Boulder lies JILA , a leading quantum physics degree institute created by a partnership between the University and NIST. JILA hosts its own NSF Physics Frontier Center, as well as several other centers focused on quantum computing and laser systems. Several of the scientists within JILA work closely with quantum computing companies, allowing their master’s and Ph.D. students better networking opportunities within Colorado, a growing hub of quantum activity.

11. The University of Waterloo

Canada’s University of Waterloo is one of the best well-known universities for quantum computing due to its Institute for Quantum Computing . With over 29 faculty members and 300 researchers, their quantum computing Ph.D. program works to train the next generation of the quantum workforce through global collaborations involving other universities, organizations, and quantum companies.

12. The University of Bristol

Both the Bristol Quantum Information Institute and its Quantum Engineering Technology labs help make the university one of the top places to get a Ph.D. or master’s in quantum computing. The Quantum Engineering Technology Labs develop prototypes for quantum applications, from computing to sensing to simulations. With a group of mentors and advisors, students of this quantum computing degree program will learn more about the career paths within this field and be assisted in their journey.

13. The University of Cambridge

The University of Cambridge has bolstered its reputation in quantum computing due to the company spin-offs from the university. Within the university are many research groups that study quantum devices and nano-systems. Because of its reputation, the University of Cambridge brings opportunities for network connections within the UK’s quantum hub.

14. Oxford University

Perhaps the largest center for quantum research in the UK, Oxford University ‘s quantum computing graduate program hosts 38 different research teams and over 200 researchers. As their focus is to harness the power of quantum computing, students get hands-on experience developing next-level quantum technology, while being in the center of the UK’s quantum network.

15. Ecole Polytechnique

The Institut Polytechnique de Paris is one of France’s most prestigious universities, as it hosts the Center for Theoretical Physics ( CPHT ). Their quantum physics degree programs offer students a wide range of physics topics, from condensed matter to particle physics.

16. Delft University of Technology

Located in the Netherlands, Delft University’s Department of Quantum and Computer Engineering ( QCE ) combines computer science with quantum computing. In their quantum engineering degree program, students research quantum architecture and circuitry, combining it with computer design.

17. Austrian Academy of Sciences

The Institute for Quantum Optics and Quantum Information ( IQOQI ) lies within the Austrian Academy of Sciences. Their quantum computing degree programs range from quantum optics to superconducting quantum circuits to quantum nanophysics. With a large staff of researchers and scientists, this quantum computing university sits right in the middle of the quantum hub in Europe.

18. University of Science and Technology of China (USTC)

The USTC’s Division of Quantum Physics and Quantum Information is a world leader in quantum computing research. Scientists and students at this center focus on fiber-based quantum communication, free-space quantum communication, quantum memory, superconducting quantum computing, quantum simulation, and many other fields. With an electronics shop and over 37 faculty members, the USTC will no doubt continue to be one of the leading quantum computing degree programs.

19. The National University of Singapore (NUS)

The NUS’s Center for Quantum Technologies ( CQT ) focuses on bringing quantum computing students and scientists from around the world together to develop quantum devices. The CQT focuses on quantum research and education as well as quantum technology. Every year, the CQT runs a short-film competition about quantum technology called Quantum Shorts .

20. The University of Sydney

The University of Sydney is a growing location for quantum computing research, partially due to Australia’s first quantum computing conference last year. Research at the University of Sydney ranges from theoretical to experimental, offering a wide range of quantum computing masters and Ph.D. programs for graduate students. The University also works with many different organizations, including the Sydney Quantum Academy.

If you found this article to be informative, make sure to explore more of the current quantum technology news  here . If you would like to explore enterprise end users of quantum in more detail, you should check out our dedicated  market intelligence platform .

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There is a worldwide research effort exploring the potentials of quantum mechanics for applications. The field began with Feynman’s proposal in 1981 at MIT Endicott House to build a computer that takes advantage of quantum mechanics and has grown enormously since Peter Shor’s 1994 quantum factoring algorithm. The idea of utilizing quantum mechanics to process information has since grown from computation and communication to encompass diverse topics such as sensing and simulations in biology and chemistry. Leaving aside the extensive experimental efforts to build controllable large-scale quantum devices, theory research in quantum information science (QIS) investigates several themes:

• If a perfectly functioning quantum computer were built, which problems could it solve faster than conventional computers, and which problems do not admit any speedup?
• What is the fundamental limitation in the computational power of our universe governed by quantum mechanics?
• How can we store, transfer, or manipulate quantum information in the presence of noise?
• How can we efficiently communicate and compute in the presence of errors?
• What are the basic properties of quantum entanglement and information?
• How can we efficiently manipulate and characterize quantum devices?
• Apart from computations and communications, what other applications can benefit from quantum hardwares?
• What are the ways to improve applications such as ultra-sensitive sensors or precise clocks?
• How can ideas from QIS contribute to other research areas as diverse as convex optimizations, black holes, and exotic quantum phases of matter?
• Is there a unified framework to efficiently describe quantum entanglement and information in complex systems?

QIS theory research at MIT spans all of these areas. The CTP faculty involved are: Soonwon Choi and Aram Harrow , and the larger group at MIT includes Isaac Chuang (EECS/physics),  Seth Lloyd (Mech. Eng.), Anand Natarajan (EECS) and Peter Shor (Math).  Other faculty in the area include Eddie Farhi (emeritus), Jeffrey Goldstone (emeritus) and Jeff Shapiro (EECS, emeritus).  Together this forms a large and vibrant group working in all areas of QIS.

Some of the notable contributions involving the CTP include the quantum adiabatic algorithm and quantum walk algorithms (Farhi, Goldstone), the first example of a problem for which quantum computers exhibit no speedup (Farhi, Goldstone), proposals for unforgeable quantum money (Farhi, Shor), a quantum algorithm for linear systems of equations (Harrow, Lloyd), efficient protocols for simulating quantum channels (Harrow, Shor), both algorithms and hardness results for testing entanglement (Harrow), proposals for quantum approximate optimization algorithms (Farhi, Goldstone), proposals and experimental observations of exotic quantum dynamics such as slow thermalization or a discrete time crystalline phase in quantum simulators (Choi), quantum sensing protocols using strongly interacting spin ensembles (Choi), and quantum convolutional neural networks (Choi). Ongoing research at MIT in QIS includes work on new quantum algorithms, efficient simulations of quantum systems, methods to characterize and control existing or near-term quantum hardwares, connections to many-body physics, applications in high-energy physics, and many other topics.

The larger QIS group at MIT shares a seminar series, a weekly group meeting, regular events for grad students.

Interdepartmental course offerings include an introductory and an advanced class in core QI/QC, as well as occasional advanced special topics classes. Quantum information has also entered the undergraduate physics curriculum with a junior lab experiment on NMR quantum computing and some lectures in the 8.04/8.05/8.06 sequence on quantum computing.

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Harvard Launches PhD in Quantum Science and Engineering

Drawing on world-class research community, program will prepare leaders of the ‘quantum revolution’.

Harvard University today announced one of the world’s first PhD programs in Quantum Science and Engineering, a new intellectual discipline at the nexus of physics, chemistry, computer science and electrical engineering with the promise to profoundly transform the way we acquire, process and communicate information and interact with the world around us.

The University is already home to a robust quantum science and engineering research community, organized under the Harvard Quantum Initiative . With the launch of the PhD program, Harvard is making the next needed commitment to provide the foundational education for the next generation of innovators and leaders who will push the boundaries of knowledge and transform quantum science and engineering into useful systems, devices and applications. 

“The new PhD program is designed to equip students with the appropriate experimental and theoretical education that reflects the nuanced intellectual approaches brought by both the sciences and engineering,” said faculty co-director Evelyn Hu , Tarr-Coyne Professor of Applied Physics and of Electrical at the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS). “The core curriculum dramatically reduces the time to basic quantum proficiency for a community of students who will be the future innovators, researchers and educators in quantum science and engineering.”

“Quantum science and engineering is not just a hybrid of subjects from different disciplines, but an important new area of study in its own right,” said faculty co-director John Doyle , Henry B. Silsbee Professor of Physics. “A Ph.D. program is necessary and foundational to the development of this new discipline.”

Quantum science and engineering is not just a hybrid of subjects from different disciplines, but an important new area of study in its own right.

“America’s continued success leading the quantum revolution depends on accelerating the next generation of talent,” said Dr. Charles Tahan, Assistant Director for Quantum Information Science at the White House Office of Science and Technology Policy and Director of the National Quantum Coordination Office. “It’s nice to see that a key component of Harvard’s education strategy is optimizing how core quantum-relevant concepts are taught.”

The University is also finalizing plans for the comprehensive renovation of a campus building into a new state-of-the-art quantum hub – a shared resource for the quantum community with instructional and research labs, spaces for seminars and workshops, and places for students, faculty, and visiting researchers and collaborators to meet and convene. Harvard’s quantum headquarters will integrate the educational, research, and translational aspects of the diverse field of quantum science and engineering in an architecturally cohesive way. This critical element of Harvard’s quantum strategy was made possible by generous gifts from Stacey L. and David E. Goel ‘93 and several other alumni .

“Existing technologies are reaching the limit of their capacity and cannot drive the innovation we need for the future, specifically in areas like semiconductors and the life sciences,” said David Goel, co-founder and managing general partner of Waltham, Mass.-based Matrix Capital Management Company, LP and one of Harvard’s most ardent supporters. “Quantum is an enabler, providing a multiplier effect on a logarithmic scale. It is a catalyst that drives scientific revolutions and epoch-making paradigm shifts.”

“Harvard is making significant institutional investments in its quantum enterprise and in the creation of a new field,” said Science Division Dean Christopher Stubbs , Samuel C. Moncher Professor of Physics and of Astronomy. Stubbs added that several active searches are underway to broaden Harvard’s faculty strength in this domain, and current faculty are building innovative partnerships around quantum research with industry.

“An incredible foundation has been laid in quantum, and we are now at an inflection point to accelerate that activity,” said SEAS Dean Frank Doyle , John A. and Elizabeth S. Armstrong Professor of Engineering and Applied Sciences.

An incredible foundation has been laid in quantum, and we are now at an inflection point to accelerate that activity.

To enable opportunities to move from basic to applied research to translating ideas into products, Doyle described a vision for “integrated partnerships where we invite partners from the private sector to be embedded on the campus to learn from the researchers in our labs, and where our faculty connect to the private sector and national labs to learn about the cutting-edge applications, as well as help translate basic research into useful tools for society.”

Harvard will admit the first cohort of PhD candidates in Fall 2022 and anticipates enrolling 35 to 40 students in the program. Participating faculty are drawn from physics and chemistry in Harvard’s Division of Science and applied physics, electrical engineering, and computer science in SEAS.

Candidates interested in Harvard’s PhD in Quantum Science and Engineering can learn more about the program philosophy, curriculum, and requirements here .

“This cross disciplinary PhD program will prepare our students to become the leaders and innovators in the emerging field of quantum science and engineering” said Emma Dench, dean of the Graduate School of Arts and Sciences. “Harvard’s interdisciplinary strength and intellectual resources make it the perfect place for them to develop their ideas, grow as scholars, and make discoveries that will change the world.”

Harvard has a long history of leadership in quantum science and engineering. Theoretical physicist and 2005 Nobel laureate Roy Glauber is widely considered the founding father of quantum optics, and 1989 Nobel laureate Norman Ramsey pioneered much of the experimental foundation of quantum science.

Today, Harvard experimental research groups are among the leaders worldwide in areas such as quantum simulations, metrology, quantum communications and computation, and are complemented by strong theoretical groups in computer science, physics, and chemistry.

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Adrian Lopez works with lasers in the lab of Professor Kang-Kuen Ni. Lopez is an inaugural member of Harvard’s new Ph.D. program in quantum science and engineering.

Photos by Kris Snibbe/Harvard Staff Photographer

Adrian Lopez keeps pretty busy.

He’s taking two highly advanced courses in quantum science and engineering, each of which assigns complex problem sets that take about five hours apiece to complete. In his free time Lopez can usually be found in the lab of Harvard Professor Kang-Kuen Ni , whose chemistry and physics lab designs new experiments to study fundamental chemical reactions and physical dynamics by slowing them down in super-cold environments.

He sits in on three hours of meetings per week at the lab and also works on his own quantum project when time allows. That project is to build a laser that can cool and trap molecules and control their quantum state interactions.  The work involves hours of tinkering with wiring and electronics as well as putting the physical parts together and aligning them all.

All in all, Lopez’s first semester at Harvard has a bit of a hustle, but the first-year graduate student from Santa Barbara, California — who dreams of one day being a professor at a research university — says it’s worth it. He feels fortunate to be getting the kind of unique background he’s getting as an inaugural member of Harvard’s new Ph.D. program in quantum science and engineering .

“The weeks fill up, but I’ve been learning a lot and really enjoying it,” he said. “I can definitely get [where I want to be].”

Launched in spring 2021 , the new quantum program is one of the world’s earliest Ph.D. programs in the subject and is designed to prepare future leaders and innovators in the critical and fast-emerging field.

This semester, 11 students, including Lopez, have been settling in as the first-ever cohort. Since September, they have started making Harvard their home and grappling with their studies in quantum information, systems, materials, and engineering.

The hope is that the extensive research experience they receive — combined with coursework and the mentorship embedded in the program ­­— will help give them a broad and well-rounded education to go on to careers in quantum, whether as an educator in academia, or developing next-level systems and applications as a researcher at a university, a national laboratory, or in industry.

“When you have a new intellectual area it’s a good idea to train students in it and to come up with a curriculum that’s really tailored to that area — in this case: an understanding of the engineering and the science behind new quantum technologies,” said  John Doyle , Henry B. Silsbee Professor of Physics and co-director of the Harvard Quantum Initiative, of which the new program is a part. “You develop these new ideas into a real firm bedrock on which students can go on to do whatever they want to do.”

Quantum mechanics and technology cut across disciplines. Advances in the field promise to usher in real-world breakthroughs in health care, quantum computing infrastructure, cyber security, drug development, climate-change prediction, machine learning, communication technologies, and financial services. The backgrounds of students who have been accepted into the program reflect that diversity — they range from physics and computer science to chemistry, electrical engineering, and math.

The well-rounded curriculum on offer was one of the driving factors for many of the students enrolling. In fact Quynh Nguyen, an international student from Vietnam who studied physics and computer science as an undergrad at MIT, said that the interdisciplinary nature of the field is what makes him so passionate about it.

“There are just so many questions to explore,” Nguyen said.

As a part of the program, he hopes to learn more about quantum information and algorithms and explore the capabilities of quantum systems such as the programmable quantum simulator being worked on in the lab of physics professor Mikhail Lukin, work that will eventually lead to a new world of ultra-fast computing.

A major focus of the new program is research experience. Along with rigorous course loads, students begin lab rotations in the first year and continue that through the rest of the program. They are also strongly encouraged to pursue cross-disciplinary research and industry internships. The idea is to give students an understanding of how research is done in different labs.

Some of the students’ research falls on the side of theory, like Nguyen’s work. Other research is more experimental, like Lopez’s work with lasers. Youqi Gang, who’s exploring experimental platforms for quantum simulation and quantum computation, is doing her first rotation in Markus Greiner’s lab studying ultracold quantum gases. Gang is gradually learning to operate the many optics, electronics, and control systems the lab uses to cool and manipulate atoms.

“The equipment is very complicated,” Gang said. “We have many different laser beams and everything needs to be very well aligned … and we have to do some day-to-day alignments and calibrations. People have put in a lot of thought about how to optimize the equipment. It’s a very cool process to be able to kind of get familiar with such a complicated machine and learn how to use it.”

Students in the program will receive their degree from the Graduate School of Arts and Sciences. The faculty for the Ph.D. program are drawn from the departments of Physics and of Chemistry and Chemical Biology in the Division of Science and the Harvard John A. Paulson School for Engineering and Applied Sciences. Students say the different class options offer them the chance to explore quantum science across the disciplines.

Nazli Ugur Koyluoglu, an international student from Istanbul, for example, is taking two very different classes this semester: Physics 271, which covers topics in quantum information, and Physics 295a, which looks at quantum theory applied to solid-state physics.

When not in class or research labs, students often can be found in the designated office space set up for them on the fifth floor of the Laboratory for Integrated Science and Engineering building. The large area is divided into two shared offices with working stations in each section and a big meeting room.

The meeting space is where students gather for weekly lunches and host weekly journal clubs where they present on different topics in quantum science, whether it’s something in a scientific journal that got their attention, something they themselves are studying, or a theory or experiment someone wants to learn more about.

The efforts have helped them quickly develop into a tight-knit community.

“It’s helped us start creating a culture for the program,” Koyluoglu said. “It’s constantly being up to date about each other’s work, which is really enlightening and helps us find out the different paths and the different questions that people are thinking about.”

HQI administrators for the Ph.D. program anticipate enrolling up to 60 students in the program in the future.

“The first cohort of students in the program are exceptional in their talents, vision, and enthusiasm in embracing a ‘quantum future,’” said Evelyn L. Hu , the Tarr-Coyne Professor of Electrical Engineering and Applied Science at SEAS and co-director of the Harvard Quantum Initiative. “My hopes are that the program and its students continue to build on this strong platform: diverse and multifaceted in its outlook and opportunities, while maintaining a strong sense of community even as the program expands.”

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Princeton University

Princeton engineering, princeton introduces a ph.d. program at intersection of quantum physics and information theory.

November 13, 2023

Princeton University has launched a new Ph.D. program in Quantum Science and Engineering , providing graduate training in an emerging discipline at the intersection of quantum physics and information theory.

This new field of quantum information science may enable fundamentally new technology, including new types of computers that can solve currently intractable problems, communication channels guaranteed secure by the laws of physics, and sensors that offer unprecedented sensitivity and spatial resolution.

Applications from prospective students are due December 15 for an incoming first class in Fall 2024. 

The new doctoral program is part of Princeton’s expanded commitment to quantum science and engineering research and education. The University’s growing programs, along with the ongoing recruitment of top faculty, graduate students, and postdoctoral researchers, reflect the University’s recognition of the transformative potential of quantum science and technology to benefit society in the decades ahead.

According to Andrew Houck, professor of electrical and computer engineering and co-director of the Princeton Q uantum I nitiative , Princeton is “ramping up efforts across campus to remain the leading place in the world for this kind of science and engineering for many decades.”  Ali Yazdani, the Class of 1909 Professor of Physics and co-director alongside Houck, adds that Princeton’s work in this area stands apart from quantum research at other institutions due to the University’s inclusive approach across disciplines and across the spectrum from foundational science to innovative devices. 

 “A major goal of the program is to form a graduate student community spanning disciplines and research topics, and united by a common scientific language,” according to Nathalie de Leon, associate professor of electrical and computer engineering and the director of graduate studies for quantum science and engineering. “Our curriculum will place students in an excellent position to build new quantum systems, discover new technological innovations, become leaders in the emergent quantum industry, and make deep, lasting contributions to quantum information science.”

De Leon says the new quantum science and engineering doctoral program is structured to take advantage of the unique interdisciplinary breadth of Princeton’s quantum community. “Research at Princeton encompasses every layer of the quantum technology stack, bringing together many-body physics, materials, devices, new quantum hardware platforms, quantum information theory, metrology, algorithms, complexity theory, and computer architecture,” explains de Leon. “This vibrant environment allows for rapid progress at the frontiers of quantum science and technology, with cross-pollination among quantum platforms and approaches.”

The initiative also benefits from a growing number of collaborations with scientists at the Princeton Plasma Physics Laboratory, a U.S. Department of Energy national laboratory managed by Princeton; the collaborative work includes designing highly specialized materials such as diamonds and superconducting magnets needed for quantum experiments and technologies.

De Leon adds, “The quantum faculty at Princeton value interdisciplinarity, collaboration, depth, and fostering a close-knit community that enables fundamental and significant advances.”

The new doctoral program will provide students with a strong foundation of fundamentals, as well as opportunities to explore the frontiers of current research, instruction on reading and understanding literature over an extensive range of topics, and many opportunities for scientific interaction and professional development. 

Princeton University’s stipend for graduate students is among the highest in the nation. The University fully funds all Ph.D. students, offering generous tailored support across all years of regular program enrollment. The graduate student experience at Princeton encompasses campus housing, a health plan and benefits, family care assistance, and a wide range of student life programs and traditions that welcome all to participate in the diverse and inclusive Graduate School community.

Prospective students are encouraged to review the degree program requirements and indicate on the application their interest in the broad research areas of quantum systems experiment, quantum systems theory, quantum material science, or quantum computer science. 

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The PhD in Quantum Science and Engineering program provides students with the opportunity to study with some of  the most prominent researchers  working in both fundamental and applied aspects of quantum science. The program encompasses a variety of engineering topics that will help shape the quantum future. This includes quantum computing, quantum communications, and quantum sensing, as well as research in quantum materials. Students have the option of working with one or more thesis advisors to build a cross-cutting research project that touches multiple disciplines.

Our graduate students work within a growing nexus of quantum research in Chicago, which includes the  Chicago Quantum Exchange , two Department of Energy funded national quantum information science research centers  Q-NEXT  and  SQMS , the  NSF QuBBE Quantum Leap Challenge Institute , one of the  longest ground-based quantum communication channels  in the country, and much more.

Students perform their research in state-of-the-art facilities at both the  University of Chicago  and  Argonne National Laboratory  campuses, and have opportunities to gain industry expertise through interactions with UChicago’s  Booth School of Business  and the  Polsky Center for Entrepreneurship and Innovation , as well as our  industry and corporate partners . More opportunities are available through our robust programs in  career development and entrepreneurship ,  science communication ,  mentoring training and opportunities , and  educational outreach .

Program overview

Learn more about our curriculum structure, inclusive and student-centered approach to education and research, programs to support career development, and more.

Enroll today

Learn more about the application process.

Noah Glachman

Bernien Lab

“Quantum computing has the potential to solve some of the world's biggest problems. I'm proud to be a part of a team here making that happen.”

Anchita Addhya

“PME brings these diverse fields together and has this very collaborative environment that I really appreciate.”

José A. Méndez

Awschalom Lab (co-advised by Hannes Bernien)

“Study something that you find interesting and I guarantee we can use you here.”

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Harvard launches phd in quantum science and engineering.

Harvard University announced today one of the world’s first PhD programs in Quantum Science and Engineering,  a new intellectual discipline at the nexus of physics, chemistry, computer science and electrical engineering with the promise to profoundly transform the way we acquire, process and communicate information and interact with the world around us.

With the launch of the PhD program, Harvard is making the next needed commitment to provide the foundational education for the next generation of innovators and leaders who will push the boundaries of knowledge and transform quantum science and engineering into useful systems, devices and applications. 

"The new PhD program is designed to equip students with the appropriate experimental and theoretical education that reflects the nuanced intellectual approaches brought by both the sciences and engineering," said faculty co-director Evelyn Hu, Tarr-Coyne Professor of Applied Physics and of Electrical at the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS). "The core curriculum dramatically reduces the time to basic quantum proficiency for a community of students who will be the future innovators, researchers and educators in quantum science and engineering."

"Quantum science and engineering is not just a hybrid of subjects from different disciplines, but an important new area of study in its own right,” said faculty co-director John Doyle, Henry B. Silsbee Professor of Physics.“A Ph.D. program is necessary and foundational to the development of this new discipline."

The new program lies at the interface of physics, chemistry, and engineering, providing students with exciting opportunities to explore the fundamentals, realizations, and applications of QSE. Students of diverse backgrounds will benefit from an integrated curriculum designed to dramatically reduce the time to basic quantum proficiency and to equip students with experimental and theoretical education that reflects the nuanced intellectual approaches brought by both the sciences and engineering. Students will have the opportunity to work with state-of-the-art experimental and computational facilities. Integrating a new approach to interdisciplinary scholarship, graduates of the program will be prepared for careers in academia, industry, and national laboratories.

Research is a primary focus of the program, with students beginning research rotations in their first year. Extensive mentoring and advising is embedded in the program: graduate students in QSE are part of an academic community that cuts across departments and schools and, as such, are strongly encouraged to pursue cross-disciplinary research. In addition to their research, QSE PhD students will receive training in communication and professional opportunities, such as industry internships.

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PhD in Quantum Information

The  PhD in Quantum Information  is designed to provide students with knowledge of quantum information, including both theory and its implementations, advanced expertise in quantum information science and in home program disciplines, as well as training in research. 

This unique interdisciplinary doctoral program is a collaboration between the Institute for Quantum Computing and the following faculties and departments at the University of Waterloo.

Faculty of Mathematics

• David R. Cheriton School of Computer Science
• Applied Mathematics
• Combinatorics and Optimization

Faculty of Engineering

• Electrical and Computer Engineering

Faculty of Science

• Physics and Astronomy

Students will be especially well-prepared for careers as scholars and researchers, with advanced expertise in quantum information science, together with the focus of their home programs. This program is designed to provide students with knowledge of quantum information, including both theory and its implementations, advanced expertise in quantum information science and in home program disciplines, as well as training in research. Further details and program requirements can be found in the graduate academic calendar .

Note: The School of Computer Science does not accept part-time students into the PhD programs unless the applicant is currently an employee of the School.

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PhD in Physics With Concentration in Quantum Information Science

We offer the PhD degree in Physics with a Concentration in Quantum Information Science (QIS).  To earn the degree a student follows the same sequence of core courses as the standard PhD in Physics, but different elective requirements. It requires a minimum of 48 semester hours of graduate work exclusive of dissertation.  These hours must include:  

• PHYS 466, 505, 511, 521, 522
• "Introduction to Quantum Information Science" (Special Topics: PHYS 480/581 and ECE 595).
• PHYS 566 (Quantum Optics)
• 571 (Quantum Computation)
• 572 (Quantum Information Theory)
• 581 (Special Topics, Quantum Optics II)
• ECE 595 (Special topics:  Quantum Error Correction)
• ECE 595 (Special topics:  Quantum Communication)
• CHE 471/587 (Special Topics: QC2: Quantum Computing for Quantum Chemistry)
• One additional approved elective from the list approved for the PhD in Physics or from the above listed electives

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Ohio State to launch quantum MS/PhD program with funding from NSF

An interdisciplinary team at The Ohio State University  has received $3 million from the National Science Foundation  to support the launch of a new graduate program in quantum information science and engineering (QISE). Faculty leaders from the College of Arts and Sciences and the College of Engineering are involved in the program, which is one of a few in the U.S. that is not housed in a single academic department.

Fruitful Research

Repouliou studies fruit flies to uncover the molecular mechanisms that enable proteins to work.

Cold Facts about Global Warming

Research by PhD student Kara Hartig could help forecasters predict weather patterns as climate change makes them more extreme.

How Animals Communicate

PhD student Ciara Sypherd unravels the mysteries of animal communication and cognition, bringing us closer to understanding the intricate languages of our non-human counterparts. 

Performing Latinx

During the nineteenth century, Latinx performers and groups often traveled from Latin America to the United States and Europe. Christofer Rodelo, PhD '22, tells the story of one Salvadoran duo that became "a fantastical representation of a lost Indigenous people." 

Princeton Launches Interdisciplinary PhD Program in Quantum Science and Engineering

Princeton Graduate School offers a PhD program in Quantum Science and Engineering, a new discipline at the intersection of quantum physics and information theory. The program aims to train students in the development of new quantum technologies, including advanced computers and highly sensitive sensors. The curriculum includes a three-course core and opportunities to explore current research. The program is unique in its interdisciplinary approach, combining many-body physics, materials, devices, quantum information theory, and computer architecture. Students typically enter the program with a degree in physics, electrical engineering, computer science, chemistry, materials science, or a related discipline.

There are now a range of specialized quantum courses available at various levels from undergraduate to masters to Ph.D. level.

Quantum Science and Engineering PhD Program at Princeton

The program promises to enable fundamentally new technological applications. These include new types of computers capable of solving currently unsolvable problems, communication channels with security guaranteed by the laws of physics, and sensors that offer unprecedented sensitivity and spatial resolution.

“Our curriculum places students in an excellent position to build new quantum systems, discover new technological innovations, become leaders in the emergent quantum industry, and make deep, lasting contributions to quantum information science.” – Princeton Graduate School

Interdisciplinary Research at Princeton

The Quantum Science and Engineering community at Princeton is unique in its interdisciplinary breadth combined with foundational research in quantum information and quantum matter. Research at Princeton encompasses every layer of the quantum technology stack. This includes many-body physics, materials, devices, new quantum hardware platforms, quantum information theory, metrology, algorithms, complexity theory, and computer architecture.

This vibrant environment allows for rapid progress at the frontiers of quantum science and technology, with cross-pollination among quantum platforms and approaches. The research community strongly values interdisciplinarity, collaboration, depth, and fostering a close-knit community that enables fundamental and impactful advances.

Curriculum and Learning Approach

The curriculum of the Quantum Science and Engineering program is designed to place students in an excellent position to build new quantum systems, discover new technological innovations, and make deep, lasting contributions to quantum information science. The program aims to provide a strong foundation of fundamentals through a three-course core, as well as opportunities to explore the frontiers of current research through electives.

First-year students are also required to take a seminar course that is associated with the Princeton Quantum Colloquium, in which they closely read the associated literature and discuss the papers. The curriculum has a unique emphasis on learning how to read and understand current literature over a large range of topics. The curriculum is complemented by many opportunities at PQI for scientific interaction and professional development.

Student Cohort and Professional Development

A major goal of the program is to help form a tight-knit graduate student cohort that spans disciplines and research topics united by a common language. Most students enter the program with an undergraduate degree in physics, electrical engineering, computer science, chemistry, materials science, or a related discipline.

When students apply , they should indicate what broad research areas they are interested in: Quantum Systems Experiment, Quantum Systems Theory, Quantum Materials Science, or Quantum Computer Science.

Application Process

The application for the Quantum Science and Engineering program can be found through the Princeton Graduate School portal. Prospective students can find complete information about the program structure and requirements from Princeton Graduate School.

“Most students enter the program with an undergraduate degree in physics, electrical engineering, computer science, chemistry, materials science, or a related discipline. When you apply, you should indicate what broad research areas you are interested in: Quantum Systems Experiment, Quantum Systems Theory, Quantum Materials Science, or Quantum Computer Science.” – Princeton Graduate School

Quick Summary

Princeton Graduate School is offering a PhD program in Quantum Science and Engineering, a new discipline that combines quantum physics and information theory, with potential applications in creating new forms of matter, understanding the emergence of the classical world, and developing new technologies such as quantum computers. The program aims to equip students with the skills to build new quantum systems, discover technological innovations, and contribute to quantum information science, with a curriculum that includes a strong foundation of fundamentals, opportunities to explore current research, and a focus on understanding current literature over a wide range of topics.

• Princeton Graduate School offers a PhD program in Quantum Science and Engineering, a new discipline at the intersection of quantum physics and information theory.
• The program aims to explore the potential of quantum mechanics, including the creation of new forms of matter, understanding the emergence of the classical world, and our basic understanding of space and time.
• The program also explores new technological applications, such as new types of computers that can solve currently intractable problems, communication channels with security guaranteed by the laws of physics, and sensors with unprecedented sensitivity and spatial resolution.
• The Princeton Quantum Science and Engineering community is unique for its interdisciplinary breadth and foundational research in quantum information and quantum matter.
• The curriculum aims to provide a strong foundation of fundamentals, as well as opportunities to explore current research through electives.
• The program is designed to prepare students to build new quantum systems, discover new technological innovations, become leaders in the emergent quantum industry, and make deep, lasting contributions to quantum information science.
• Most students enter the program with an undergraduate degree in physics, electrical engineering, computer science, chemistry, materials science, or a related discipline.

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PhD track Quantum Science and Technologies (QUANTIX)

WHY ENROLL IN THIS PROGRAM?

Get ready for a PhD by starting research at an early stage

Be closely associated with the research activities carried out in a world-renowned innovation cluster

Benefit from individual and personalized supervision by a faculty member

• Description
• Associated Laboratories
• PhD Tracks Research Projects

Quantum Technologies have seen a dramatic development in the past few years. The realization of individual quantum systems and the control of new materials with unconventional properties has paved the way to the development of machines and protocols based on the most fundamental aspects of quantum mechanics, without classical counterparts, such as the superposition of states and entanglement. The demonstration of quantum supremacy in 2019 has been a major step, but many new challenges remain to be taken for the complete deployment of Quantum Technologies, at both the fundamental level and that of practical applications.

The Quantum Science and Technologies PhD track is organized around six pillars:

• Quantum Materials
• Quantum Simulation
• Quantum Computation
• Quantum Sensing and Metrology
• Quantum Communication and Networking
• Quantum Information Processing

It aims at providing the students with a high level education at the state of the art of quantum physics and quantum information processing in direct contact with forefront research in all these fields.

• Be trained to forefront challenges in quantum science and its technological applications
• Contribute to cutting-edge research in a word-leading research center
• Discover a multidisciplinary field at the frontier of theoretical and experimental physics, computer science, and applied mathematics.
• Discover the diversity of quantum technologies in the rich scientific environment of the Plateau de Saclay
• Become a leader of the next generation of reserachers and engineers in quantum science and technologies

Partner University

• Université Paris-Saclay

The five-year curriculum of the PhD track trains students in cutting-edge research for them to pursue international careers  in prestigious universities and academic labs or leading companies in quantum technologies. 

The PhD Track provides a five-year "à la carte" integrated Master and PhD program for particularly motivated and talented students aiming at preparing a career in academia or industry through an individualized research-oriented training program in Quantum Science and Technologies. Students will be attributed an academic tutor in their field of research from the very start of their studies at IP Paris. In coordination with their tutor, students will elaborate their own personal curriculum consisting of course work and research phases corresponding to their research interests and professional project.

During their first year, students will follow a selection of high level courses focused on quantum physics and its interfaces. It may include computer science and applied mathematics courses, as well as complementary modules allowing them to broaden their general scientific culture and to acquire complementary skills. At the same time, the students are immediately members of the research team of their tutor and participate in team activities and research discussions. This includes in particular attending relevant research seminars and potentially topical workshops. During the first year, students will work on a research project, in collaboration with their host team. A significant part of the second year will be devoted to a larger-scale research work, giving rise to a Master thesis and – most likely – first research publications. This is also the occasion to consolidate their choice for the topic of their PhD.

While it will still be possible to follow selected – more specialized – scientific courses and courses in secondary skills, the last three years of the PhD Track program will be mainly devoted to research work towards the PhD degree.

In addition to the weekly laboratory work, two mandatory full-time internships take place during the spring, one at the M1 level, the other at the M2 level. The duration and corresponding number of ECTS are at least those of the main Master in which the student is enrolled. The number of ECTS can be adapted depending on the duration of the internship.

Students have the opportunity to visit international partner universities.

All relevant laboratories of IP Paris and partner institutions, in particular

• Center for Theoretical Physics (CPHT, Ecole Polytechnique
• Laboratory for Applied Optics (LOA, Ecole Polytechnique/ENSTA)
• Laboratory for Condensed Matter Physics (PMC, Ecole Polytechnique)
• Laboratory for Information Processing and Communication Laboratory (LTCI, Telecom Paris)
• Laboratory for Irradiated Solids (LSI, Ecole Polytechnique)

Admission requirements

Academic prerequisites.

Completion with highest honors of a Bachelor in physics, including courses in quantum physics, at Institut Polytechnique de Paris or equivalent in France or abroad.

Evidence of research potential is essential as the main goal of such a PhD program is to train first class researchers. 

Students who have completed the first year of an equivalent program may exceptionally be directly admitted to the second year (4-year PhD program).

Language prerequisites

A certificate of proficiency in English (level B2) is required (TOEIC, IELTS, TOEFL, Cambridge ESOL), except for native speakers and students who previously studied in English.

How to apply

Applications are exclusively online. You will be required to provide the following documents:

• Transcript 
• Two academic references (added online directly by your referees)  
• CV/resume 
• Statement of purpose indicating which 2 choices of research subjects among the one listed on this page under the section "PhD Track Research Projects"

You will receive an answer in your candidate space within 2 months following the closing date of the application session. 

Fees and scholarships

Estimated fees for 2022-2023 are subject to increase

• Regular fees: 243€
• Engineer students enrolled in one of the five member schools of Institut Polytechnique de Paris (Ecole polytechnique, ENSTA Paris, ENSAE Paris, Télécom Paris and Télécom SudParis): 159€
• Special cases: please refer to the "Cost of studies" section of the FAQs

Applications and admission dates

Coordinator.

• Luca Perfetti 

General enquiry

• [email protected]

When applying to the PhD Tracks in Physics, you should describe your preferred fields of study and research in your motivation letter. You are ecouraged to choose two preferred PhD Track subjects among the list below.   Since the posted offers do not cover the full spectrum of our activities , you can also visit the web pages of the 11 laboratories (CPHT, IPVF, LLR, LOA, LOB, LPICM, LPMC, LPP, LSI, LULI, Omega) affiliated to the physics department and indicate the research lines that interest you the most.

PhD Track research projects in “QUANTUM SCIENCE AND TECHNOLOGY”

• Correlated quantum matter and quantum information
• Ultrafast dynamics of electrons in quantum materials
• Re-using model results to determine materials properties: connector theory approach
• Collective electronic fluctuations and their influence on materials properties
• Spin-dependent charge dynamics in dilute nitride and defect-engineered semiconductor quantum structures and devices
• Electronic processes in nitride semiconductor quantum structures and devices
• Theory of Many-Body Quantum States
• Probing the quantum properties of spin defects in 2D materials
• Time-frequency quantum information processing
• Uncovering a new law of physics in quantum materials

Faraday Discussions

What can quantum information theory offer to quantum chemistry.

It is the ultimate goal of this work to foster synergy between quantum chemistry and the flourishing field of quantum information theory. For this, we first translate quantum information concepts such as entanglement and correlation into the context of quantum chemical systems. In particular, we establish two conceptually distinct perspectives on correlation leading to a notion of orbital and particle correlation. We then demonstrate that particle correlation equals orbital correlation minimized with respect to all orbital reference bases. Accordingly, particle correlation resembles the minimal, thus intrinsic, complexity of many-electron wavefunctions while orbital correlation quantifies their complexity relative to a basis. We illustrate these novel concepts of intrinsic and extrinsic correlation complexity with analytic and numerical examples, which also demonstrates the crucial link between the two correlation pictures. Our results provide theoretical justification for the long-favored natural orbitals for simplifying electronic structures, and open new pathways for developing more efficient approaches towards the electron correlation problem.

• This article is part of the themed collection: Correlated electronic structure

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D. Aliverti-Piuri, K. Chatterjee, L. Ding, K. Liao, J. Liebert and C. Schilling, Faraday Discuss. , 2024, Accepted Manuscript , DOI: 10.1039/D4FD00059E

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U.S. News Ranks UT Austin Computer Science Among Best in Graduate Program Rankings

The 2024-2025 rankings tout computer science at The University of Texas at Austin as among the seven best nationally.

U.S. News and World Report graduate rankings

The University of Texas at Austin continues to be one of the premier schools for graduate studies, according to U.S. News & World Report’s partial release of its most recent “Best Graduate Schools.” UT made gains in several disciplines, including computer science.

Overall, the University has 42 graduate schools and specialty programs ranked in the top 10 when combined with previous years, including a dozen in the College of Natural Sciences. The publication updates some of its specialty rankings each year and republishes the most recent rankings in other areas. Additionally, U.S. News delayed release of some rankings.

“These numbers are meaningful. Having more than 40 schools, programs and specialties ranked in the top 10 in this partial release alone, including several that are the best in the country, if not the world, is reflective of our ability to continue to attract exceptional faculty and students,” said President Jay Hartzell. “Our talent is what puts UT at the leading edge of discovery in AI and robotics, life sciences, population research, and many other disciplines that are at the forefront of solving many of the world’s most pressing problems and bettering society.”

The College of Natural Sciences has 12 programs and specialties ranked among the top 10 in the most recent ranking for a discipline, the most of any college or school at UT Austin. Computer Science (No. 7) scored top 10 rankings in all four discipline’s specialties that are ranked within departments. 

U.S. News & World Report’s graduate rankings, which are published separately from the magazine’s yearly ranking of undergraduate programs, are considered the gold standard of graduate and professional rankings. They are based on surveys of academic leaders and, for select programs, additional quantitative measures including placement test scores, student/faculty ratios, research expenditures and job placement success.

UT Austin graduate schools, programs and specialties within Natural Sciences that U.S. News & World Report ranked this year or last are listed below.

Chemistry – 16*

• Analytical – 4*
• Inorganic – 14*
• Organic – 20*
• Physical – 14*

Computer Science – 7

• Artificial Intelligence – 9
• Programming Language – 7
• Systems – 10

Mathematics – 13*

• Algebra / Number Theory / Algebraic Geometry – 19*
• Analysis – 8*
• Applied Math – 7*
• Topology – 8*

Physics – 13*

• Cosmology/Relativity/Gravity – 10*
• Condensed Matter – 22*

Statistics – 27* 

* Ranking not revised for 2024-25.   In the most recent life science rankings from U.S. News, UT Austin ranked in the top 25 for biological sciences, including ranking 8th in ecology/evolutionary biology; in the most recent ranking for plasma physics, UT ranked third.

Read the full UT press release

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Announcements

New Advanced Quantum Science Institute Will Bridge Basic Research and Applied Science

April 5, 2024 • by Marc Airhart

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March 26, 2024 • by Steven E. Franklin

Undergraduate Researchers Help Unlock Lessons of Machine Learning and AI

March 20, 2024 • by Amelia Engstrom

University of Houston Lands 18 Programs in Latest QS World University Rankings

By Shawn Lindsey — 713-743-5725

• University and Campus

The University of Houston is, once again, demonstrating its strength as a global leader. UH has 18 programs ranked among the top in the world according to the 2024 edition of the QS World University Rankings by Subject , released today by QS Quacquarelli Symonds.

UH’s hospitality programs in the Conrad N. Hilton College of Global Hospitality Leadership led the way with a world rank of No. 35. The petroleum engineering program in the Cullen College of Engineering also ranked in the top 100 worldwide (51-100).

In its annual list, QS evaluated 55 narrow academic disciplines and five broad faculty areas by analyzing the reputation and research output of almost 5,000 institutions worldwide. In total, it provides independent comparative analysis on the performance of more than 16,400 individual university programs in 96 locations around the world.

“We are pleased to have yet one more accolade confirming the quality of our programs. Our faculty members are at the forefront of groundbreaking research spanning various fields, positioning UH as a global leader in advancing societal progress and fostering innovation,” said Diane Z. Chase, senior vice president for academic affairs and provost.

In addition to the 18 individual subjects that were ranked, UH’s earned an overall world ranking in three of the five broad disciplines: engineering and technology, natural sciences, and social sciences and management.

Using five key metrics— academic reputation, employer reputation, research citations, research impact and cross-border research collaboration. Of the almost 5,000 institutions evaluated, fewer than a third of the institutions earned a published world ranking. The U.S. led the rankings with 213 institutions, followed by the United Kingdom (103) and China (101).

“QS’ analysis of performance trends across nearly 16,000 university departments worldwide continues to illuminate factors influencing the quality of higher education institutions globally,” said QS senior vice president Ben Sowter. “An international outlook remains paramount, manifested through diversity of students, faculty body and research relationships. Additionally, universities experiencing upward mobility have benefited from sustained, targeted investment, highlighting the importance of government support. Meanwhile, the development of partnerships with industry correlates with improved performance in employment and research.”

UH Programs in the QS World Rankings by Subject:

Arts & Humanities

   - English Language & Literature                        

Social Sciences and Management (Overall Ranking)

   - Hospitality & Leisure Management                  

   - Accounting & Finance                                    

   - Economics & Econometrics                            

   - Education                                                    

   - Business & Management Studies

Engineering and Technology (Overall Ranking)

   - Petroleum Engineering                                  

   - Engineering – Chemical                                 

   - Engineering - Electrical & Electronic                

   - Engineering - Mechanical, Aeronautical & Ma.  

   - Computer Science & Information Systems       

Life Sciences and Medicine

   - Psychology                                                   

   - Medicine                                                      

   - Biological Sciences                                        

Natural Sciences (Overall Ranking)

   - Chemistry                                                    

   - Materials Science                                          

   - Mathematics

   - Physics & Astronomy

Top Stories

April 11, 2024

The University of Houston is, once again, demonstrating its strength as a global leader. UH has 18 programs ranked among the top in the world according to the 2024 edition of the QS World University Rankings by Subject, released today by QS Quacquarelli Symonds.

April 09, 2024

U.S. News & World Report Ranks UH Graduate Programs Among Nation’s Best in 2024

The University of Houston is once again proving that it is a powerhouse in graduate education, with 13 of its programs securing spots among the top 50 nationwide in the 2024 U.S. News & World Report graduate program rankings, released today. Three engineering programs maintain their top 50 rank pending the release of 2024 engineering rankings, which have been delayed. In total, UH has 17 programs in the top 50.

• Student, Faculty and Staff Success

March 29, 2024

Three Renowned Argonne Scientists Accept Joint Appointments at the University of Houston

Three top researchers with the U.S. Department of Energy’s Argonne National Laboratory have accepted joint appointments in various capacities at the University of Houston. This strategic collaboration furthers critical research efforts, public-private partnerships and educational opportunities for students.

• Science, Energy and Innovation

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USF School of Information MLIS Program Ranks in Top 50 U.S. Library and Information Studies Graduate Programs

• April 10, 2024
• iSchool News

The School of Information is proud to announce that our M.A. in Library and Information Science program was ranked as the 27th best Library and Information Studies program by U.S. News & World Report ! What an incredible recognition to our university, school, faculty, staff, & students.

The University of South Florida is home to nearly two dozen graduate programs considered among the best in America, according to new rankings released today by U.S. News & World Report. USF features 23 graduate programs ranked inside the top 100 among all public and private institutions, including 11 ranked in the top 50.

“We are thrilled that many University of South Florida graduate programs are included among the nation’s best in U.S. News & World Report’s rankings,” USF President Rhea Law said. “This recognition underscores the commitment of our faculty and staff, who continue to provide high-quality programs that empower our students to enhance their skills, expand their knowledge and progress in their careers by earning an advanced degree.”

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News from the University of Wisconsin-Milwaukee

Several UWM programs land high in U.S. News graduate school rankings

Two programs at UWM landed in the top 30 nationwide in the latest rankings of graduate schools by U.S. News & World Report .

UWM’s library and information science graduate program ranked No. 14, while its occupational therapy graduate program is at No. 27.

Several other graduate programs at UWM ranked in the top 100 nationwide, including:

• Clinical psychology
• Nursing – master’s
• Nursing – doctor of nursing practice
• Health care management
• Physical therapy
• Political science
• Public health
• Social work
• Speech-language pathology

In all, more than 2,000 graduate programs from more than 1,200 universities were considered.

The rankings are based on two types of data: expert opinion about program excellence and statistical indicators that measure the quality of a school’s faculty, research and students, and students’ post-graduate outcomes.

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