Faculty

Erickson, Anderson elected to National Academy of Engineering

Charles Ferrer — Fri, 13 Feb 2026 22:20:07 +0000

Erickson, Anderson elected to National Academy of Engineering Charles Ferrer Fri, 02/13/2026 - 15:20

Dana Anderson and Bob Erickson are among the 130 scientists and engineers from around the country who will be inducted as members of the NAE at a meeting this fall.

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ECEE welcomes new faculty for spring 2026

Charles Ferrer — Wed, 07 Jan 2026 15:43:41 +0000

ECEE welcomes new faculty for spring 2026 Charles Ferrer Wed, 01/07/2026 - 08:43

Charles Ferrer

ECEE at CU �鶹ӰԺ is welcoming three new faculty members including Assistant Professor Logan Horowitz and and Assistant Professor Gonzalo Constante Flores. Additionally, award-winning physicist Matt Eichenfield, the inaugural Karl Gustafson Endowed Chair of Quantum Engineering, joined this semester.

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Diddams inducted into National Academy of Engineering

Charles Ferrer — Wed, 15 Oct 2025 15:09:21 +0000

Diddams inducted into National Academy of Engineering Charles Ferrer Wed, 10/15/2025 - 09:09

Charles Ferrer

Diddams was inducted into the National Academy of Engineering at their annual meeting on Oct. 5 in Washington, DC.

Scott Diddams, professor and Robert H. Davis Endowed Chair in Discovery Learning, was inducted into the National Academy of Engineering (NAE).

Election to the NAE is one of the highest professional distinctions granted to engineers in academia and industry.

Diddams, based in the Department of Electrical, Computer and Energy Engineering and the Department of Physics, was recognized for his outstanding contributions in optical frequency combs and their applications. He joins 128 new U.S. members and 21 international members to the Class of 2025.

“Each day when I get up, I feel fortunate that my job allows me to be curious, attempt to solve hard problems and work with students and motivated people doing the same,” Diddams said. “I am truly humbled by this honor.”

Diddams carries out experimental research in the fields of precision spectroscopy and quantum metrology, nonlinear optics, microwave photonics and ultrafast lasers.

One of his current projects is a collaboration with the National Institute of Standards and Technology (NIST) and the National Oceanic and Atmospheric Administration that aims to use an optical atomic clock, to test Einstein’s theory of general relativity atop Mt. Blue Sky. This endeavor marks one of the first efforts to take ultra-precise quantum technology out of the lab and into the natural environment, opening new opportunities for navigation, geosciences and timekeeping.

I am most grateful to the students, postdocs, colleagues and mentors who have made me a better scientist, engineer and person. I am also thankful to my family for their personal support in many unseen ways.

Diddams received his PhD degree from the University of New Mexico in 1996 and completed his postdoctoral work at JILA. He also spent time as a research physicist, group leader and fellow at NIST. As a postdoc, Diddams built the first optical frequency combs in the lab of CU �鶹ӰԺ Nobel Laureate John Hall. Throughout his career, he has pioneered the use of these powerful tools for optical clocks, tests of fundamental physics, novel spectroscopy and astronomy.

In 2022, he joined the CU �鶹ӰԺ faculty, where he also assumed the role of faculty director of the Quantum Engineering Initiative in the College of Engineering and Applied Science.

His work has resulted in more than 750 peer-reviewed publications, conference papers, and invited talks, and has been recognized with numerous honors, including the Distinguished Presidential Rank Award, the U.S. Department of Commerce Gold and Silver Medals, the Presidential Early Career Award in Science and Engineering (PECASE) and the C.E.K. Mees Medal. Diddams is also a Fellow of OPTICA, IEEE and the American Physical Society.

“As a member of the NAE, it is my hope to give back to the community and country that has provided me with so much as a scientist and engineer.”

Scott Diddams was inducted into the National Academy of Engineering Class of 2025 for his outstanding contributions in optical frequency combs and their applications.

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New open-source software allows for efficient 3D printing with multiple materials

Charles Ferrer — Tue, 14 Oct 2025 14:46:52 +0000

New open-source software allows for efficient 3D printing with multiple materials Charles Ferrer Tue, 10/14/2025 - 08:46

Researchers have created an open-source design system software package that uses functions and code to map not just shapes, but where different materials belong in a 3D object. The project, called OpenVCAD, has the potential to transform 3D printing by enabling engineers to design multi-material objects smarter and more efficiently.

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Matt Eichenfield named inaugural Karl Gustafson Endowed Chair of Quantum Engineering

Charles Ferrer — Thu, 25 Sep 2025 21:17:12 +0000

Matt Eichenfield named inaugural Karl Gustafson Endowed Chair of Quantum Engineering Charles Ferrer Thu, 09/25/2025 - 15:17

Charles Ferrer

Award-winning physicist Matt Eichenfield has been named the inaugural Karl Gustafson Endowed Chair of Quantum Engineering in the Department of Electrical, Computer and Energy Engineering at CU �鶹ӰԺ.

A recognized leader in ultra-scalable photonics, nano-optomechanics and phononics, Eichenfield’s career spans academia and government. He is dedicated to advancing the frontiers of quantum science and technology, as well as classical optical and RF systems.

“CU �鶹ӰԺ is where you can assemble a team of the world’s leading experts across physics, engineering and beyond to go after really audacious goals in quantum,” Eichenfield said. “The quantum ecosystem at CU �鶹ӰԺ and Colorado is unmatched, and I’m excited to collaborate with researchers and companies who are already leading the way in quantum technologies that will impact the world.”

The endowed chair honors the career of Professor Emeritus Karl Gustafson, whose belief in multidisciplinary research anticipated the kinds of breakthroughs that now define quantum engineering.

“The Karl Gustafson Endowed Chair represents both a legacy and a vision to tackle the world’s most complex challenges,” said Keith Molenaar, dean of the College of Engineering and Applied Science. “Matt Eichenfield is an extraordinary scholar and mentor who will further strengthen our leadership in quantum engineering, and we are thrilled to welcome him to CU Engineering.”

Eichenfield most recently worked at the University of Arizona’s Wyant College of Optical Sciences, where he held the International Society for Optics and Photonics Endowed Chair and was the co-director of the Center for Quantum Networks — a National Science Foundation Engineering Research Center.

He holds a joint appointment at Sandia National Laboratories, recognizing his research and leadership at a federal lab whose mission includes state-of-the-art solutions for national security. At Sandia, he founded and led the Micro Electro Mechanical Systems–Enabled Quantum Systems group, pioneering approaches that combine advanced micro- and nano-fabrication with quantum engineering. His work has enabled devices that push the boundaries of both classical and quantum technologies.

This perspective, working within national lab facilities while mentoring students, remains central to his vision for CU �鶹ӰԺ.

“My experience in fabricating myriad nanotechnologies for classical and quantum applications gives me a unique perspective on how to engineer leading quantum systems,” he said. “I’m excited to share this with undergraduate and graduate students, teaching them how to build quantum devices and preparing them to go into the quantum industry.”

Quantum Nanophoxonics Laboratory led by Eichenfield.

Shaping the next generation of quantum scientists

Eichenfield emphasizes giving students access to the real-world challenges and partnerships that define the fast-growing quantum sector.

“Coming to CU �鶹ӰԺ means you’ll get to work with world-class faculty, along with companies revolutionizing quantum computing,” Eichenfield said. “My research group also gets to work alongside Sandia scientists who are pursuing quantum solutions vital to the U.S. economy and national security.”

His advice to students is simple but bold: Seek out the hardest problems.

“You should work on the most challenging engineering or scientific challenges you can find,” he said. “Those are the most exciting and rewarding problems to tackle and because of that they draw the best and the brightest who have to leverage the very limits of science and engineering to solve those problems. There’s no more difficult and exciting field right now than quantum computing and quantum sensing.”

A career shaped by discovery

Eichenfield’s path into physics and quantum engineering began in high school, where an inspiring physics teacher sparked his interest in science. As an undergraduate at the University of Nevada Las Vegas, he immersed himself in laboratory work, eventually joining the Laser Interferometer Gravitational-Wave Observatory project at the California Institute of Technology as a summer and then year-round intern.

He stayed on at Caltech for graduate school in physics, where he studied nanoscale photonic and phononic systems. His work centered on building devices sensitive enough to detect the tiniest possible vibrations allowed by quantum mechanics.

He explains the concept with a tuning fork analogy: Strike it and you hear vibrations. Strike it softer and softer and eventually the sound disappears. But quantum mechanics tells us that even when no energy is added, a tiny motion still remains — quantum ground-state fluctuations.

“The devices I built for my PhD were the first that could actually detect those ground-state fluctuations,” Eichenfield said. “It was both my intro to quantum science and a lesson in how engineering at the nanoscale can reveal phenomena that nothing else has ever been able to observe.”

After completing his PhD, he became the first Kavli Nanoscience Prize Postdoctoral Fellow at Caltech before joining Sandia as a Harry S. Truman Fellow.

Eichenfield — who holds 22 patents — continues to build on research and innovation. His group is developing piezoelectric optomechanical photonic circuits for quantum computers that use ions and neutral atoms as qubits, as well as novel infrared detectors with applications in spectroscopy, imaging and sensing.

Quantum’s global future

CU �鶹ӰԺ is leading a first-of-its-kind National Quantum Nanofab (NQN) facility that will provide researchers from universities, government and industry with the tools to fabricate and test innovative quantum devices. Eichenfield hopes to forge those collaborations through the NQN.

"Our legacy in scientific leadership has driven global progress in quantum science for decades,” said Massimo Ruzzene, senior vice chancellor for research and innovation. “With initiatives like our CUbit Quantum Initiative and the Colorado Quantum Incubator, CU �鶹ӰԺ is at the forefront of the development of quantum technologies, through the advances of our own faculty, as well as increased collaboration with the regional and national quantum communities. The promise of quantum technologies is going to be realized in the foreseeable future."

Eichenfield points to the so-called traveling salesman problem and other optimization problems, such as airline scheduling, global shipping logistics and supply chain management, that quantum computers could solve exponentially faster than classical computers. Quantum computing also can innovate new drug discovery, enabling researchers to simulate molecular interactions at a level of complexity that classical computers cannot achieve.

“Quantum computing will impact the lives of everyone on the planet in ways we can’t even imagine yet,” Eichenfield said. “Society has a lot to gain, and CU �鶹ӰԺ is at the forefront of making that future possible.”

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Tamara Lehman receives CAREER award to strengthen hardware security

Charles Ferrer — Wed, 12 Mar 2025 20:40:09 +0000

Tamara Lehman receives CAREER award to strengthen hardware security Charles Ferrer Wed, 03/12/2025 - 14:40

Charles Ferrer

Lehman lands the 2025 CAREER award through the National Science Foundation to advance computer architecture security.

Computers are faster than ever—but at what cost? Speed and performance have long been prioritized over security in hardware design, leaving modern systems vulnerable to attacks.

Assistant Professor Tamara Lehman, from CU �鶹ӰԺ’s Department of Electrical, Computer and Energy Engineering, is working to address these vulnerabilities in microarchitecture designs while exploring security metrics for future hardware designs.

Lehman recently received a prestigious $615,000, five-year National Science Foundation CAREER Award to advance computer architecture security.

Addressing security gaps in hardware design

Microarchitectural security is the defense mechanisms that can be added at microarchitectural design time.

“Microarchitectural security has been in the back seat for a long time. For years, we’ve focused on making computers faster without fully considering what that means for security,” Lehman said. “That’s why we’re now dealing with systems that are high-performing but often lack security guarantees.”

Microarchitectural design is the functional level design of the hardware; one level above logic gates and one level below the operating system. It is the implementation of the software interface using the hardware constructs.

Since the 2018 disclosure of the Spectre and Meltdown attacks—security vulnerabilities affecting modern processors—industry and academia have faced increasing pressure to address hardware security risks. However, the lack of standardized metrics for assessing microarchitectural security makes it difficult to compare designs and implement effective safeguards.

Lehman’s research aims to bridge this gap by integrating security metrics directly into the hardware design process.

Lehman working with PhD student, Zach Moolman, in her lab.

Evaluating microarchitectural vulnerabilities

The first phase of the project focuses on caches—critical memory structures that are among the most vulnerable components in modern processors.

Lehman and her PhD students will define security metrics for caches and integrate them into commonly used processor simulators, ensuring these tools become widely available to both researchers and industry professionals. She hopes to propose a novel approach to quantify hardware security risks.

“Right now, companies in industry make trade-offs between performance and security with little concrete data about the security guarantees afforded by defense mechanisms,” she said. “My goal is to develop standardized security metrics that allow designers to measure and compare the security of different microarchitectural components in parallel to performance.”

Once they can prove those security metrics provide a meaningful assessment of security risks, they can expand the framework to other parts of the processor microarchitecture, she said.

Real-world implications: strengthening critical infrastructure

Lehman’s research has significant implications for global cybersecurity.

“We rely on computing devices for everything from banking to autonomous vehicles,” she said. “If a microarchitectural attack compromises the hardware running an autonomous driving system, lives could be at risk.”

Beyond personal and commercial computing, her research could help protect critical infrastructure from cyberattacks, such as power grid systems and banking systems.

Lehman noted how the 2021 Colonial Pipeline cyberattack disrupted oil supply chains across the United States and a prime example of how vulnerabilities in computing systems can have far-reaching consequences.

Bringing security for hardware designs

Ultimately, Lehman’s research aims to shift the conversation from viewing security as a trade-off to seeing it as a fundamental design requirement.

“There are no standardized security metrics for hardware or for software,” she said. “We hope to establish widely accepted security evaluation methods that can be integrated into both research and industry design practices.”

“I want to move us toward a more concrete, data-driven approach where security is as quantifiable as performance in hardware design,” Lehman said.

Tamara Lehman, assistant professor of computer engineering, has earned a CAREER award through the National Science Foundation to address hardware vulnerabilities in microarchitecture designs while exploring security metrics for future hardware designs.

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Trailblazing in power electronics: Bob Erickson named Distinguished Professor

Charles Ferrer — Mon, 16 Dec 2024 20:11:03 +0000

Trailblazing in power electronics: Bob Erickson named Distinguished Professor Charles Ferrer Mon, 12/16/2024 - 13:11

Charles Ferrer

Bob Erickson, a professor of electrical, computer and energy engineering at CU �鶹ӰԺ, was recently named a CU Distinguished Professor—the highest faculty rank bestowed by the university.

Known for his pioneering contributions to power electronics and his dedication to education, Erickson reflects on his career, research and the evolving landscape of engineering education in this Q&A.

When did you first realize you wanted to pursue a career in academia?

It wasn’t a straightforward path. I always knew I wanted to be an electrical engineer. It wasn’t until the second half of my graduate studies that I began to seriously consider academia. At the time, power electronics wasn’t a widely recognized field in academia. It was niche, with only a few conferences and no dedicated journals or societies. Back then, power electronics wasn’t even considered its own discipline in most electrical engineering departments. When I came to CU �鶹ӰԺ, there was no power electronics program—just traditional power systems. Building something from scratch was a challenge, but it was also incredibly rewarding.

Over your career, what has been the most fulfilling aspect of being a professor?

It’s hard to choose just one! From the research side, it’s been amazing to see the growth of power electronics. What started as a niche area is now a critical field, impacting everything from cell phones to electric vehicles and renewable energy systems. I’ve worked on diverse projects—early electric vehicles with General Motors and Toyota, wind power converters, solar power innovations and even tiny inverters that fit into solar roof shingles. It’s nice to see the practical applications of our work influencing real-world technologies.

Biography

Erickson is a pioneering figure in power electronics whose innovative research has transformed the field and set new standards for efficiency and performance in electric vehicles, as well as in inverters for solar power, wind power and battery energy storage systems. His development of composite power converter architectures has redefined the capabilities of power electronics, leading to the creation of BREK Electronics, a successful CU spinoff where Erickson serves as Chief Technology Officer. His work has not only driven technological advancements but has also shaped the trajectory of the industry through his collaborations with government and industry partners. His research has been recognized through awards including the Institution of Electrical and Electronics Engineers (IEEE) William E Newell Award, Life Fellow of the IEEE, the CU �鶹ӰԺ Inventor of the Year and others.

Erickson’s impact on education is equally significant. His textbook, Fundamentals of Power Electronics, has become a foundational resource for engineers and educators worldwide. His dedication to advancing digital education is evident in his leadership in founding and development of the Coursera-based MS-EE program, the first fully online MS-EE degree program, with highly innovative features such as performance-based admissions that are revolutionizing access to professional education and setting a benchmark for online learning in engineering. He led the development of a Massive Open Online Course and a Coursera Specialization in Power Electronics that reached over 100,000 learners worldwide.

In addition to his research and educational contributions, Erickson has provided exceptional service to CU �鶹ӰԺ, serving as ECEE Department Chair three times, and also guiding the university’s online and professional graduate programs through critical periods of growth. His leadership has positioned CU �鶹ӰԺ as a leader in distance education, ensuring the success and continued expansion of its programs in Electrical Engineering and Power Electronics. Erickson’s enduring contributions to research, education and leadership have had a lasting impact on the field and the university.

On the teaching side, I’m particularly proud of the professional master’s programs we’ve developed. These programs meet the needs of working engineers and provide pathways for students who might not otherwise have access to traditional graduate education. The online courses through Coursera have been a revolutionary—reaching thousands of students globally and showing the transformative power of education.

Speaking of online education, you were an early adopter of MOOCs (Massive Open Online Courses). How has that experience shaped your teaching philosophy?

MOOCs were a game-changer. When CU �鶹ӰԺ partnered with Coursera, my power electronics course was one of the first we launched. I was blown away when 45,000 people signed up. Running the course multiple times, with forums buzzing in multiple languages, was humbling. The most rewarding part was reaching people who wouldn’t otherwise have access to this education—working parents, professionals and even stay-at-home parents looking to learn. It demonstrated the potential of online platforms, and it’s been exciting to see the university build on that foundation with full degree programs.

Your research spans several industries. What has been the most fulfilling aspect of that work?

Seeing power electronics evolve from a niche field into a cornerstone of modern technology has been incredible. When I started, it was all about things like computer power supplies and aerospace systems. Over time, I’ve worked on electric vehicles, solar power, wind energy and energy storage systems. For example, I collaborated on early hybrid electric vehicle projects, helped develop tiny inverters for solar shingles in Silicon Valley and worked on large-scale solar and battery storage solutions. Power electronics now touch everything, from cell phones to wind turbines, and it’s rewarding to have contributed to that growth.

What’s next for the world of power electronics?

Power electronics is really about bringing sophisticated control to electrical power—at scales ranging from fractions of a watt to gigawatts. It’s fundamental to innovations like the smart grid and electric vehicles. Power electronics is all about improving the efficiency and control of electrical power across scales—from tiny devices to massive infrastructure. It’s integral to electric vehicles, renewable energy systems and grid modernization. I see even greater integration of electronics into power applications. Smart grids, for instance, are still a bit nebulous as a concept, but power electronics will be at the heart of making those systems work. The field is constantly evolving, and that’s what keeps it exciting.

You co-founded Breck Electronics. How has that experience shaped your perspective?

Starting Breck Electronics was unexpected. It came out of an ARPA-E project where commercialization was strongly encouraged. Although I initially took a backseat role, I became more involved over time. It’s been a journey full of challenges and successes, from developing unique products to navigating ups and downs in the startup world.

Outside of your professional work, what are some of your personal interests?

I enjoy cooking with my wife and exploring culinary experiences. In my earlier days, I was very involved in music—playing instruments like clarinet, guitar, bassoon and piano. Even though I don’t play much anymore, I still enjoy listening to classical music and seeking out great restaurants during our travels.

What does this honor of being named a Distinguished Professor mean to you?

It’s a very nice recognition from the university. It acknowledges not just my work but the contributions of everyone who supported me along the way.

Bob Erickson, a professor of electrical, computer and energy engineering at CU �鶹ӰԺ, was recently named a CU Distinguished Professor—the highest faculty rank bestowed by the university.

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Jensen joins ECEE in the systems and controls research area

Anonymous — Tue, 29 Aug 2023 06:00:00 +0000

Jensen joins ECEE in the systems and controls research area Anonymous (not verified) Tue, 08/29/2023 - 00:00

The Department of Electrical, Computer and Energy Engineering at the �鶹ӰԺ is welcoming Emily Jensen to our teaching and research community.

Jensen is joining as an assistant professor in the systems & controls research area, and will begin in spring 2024. Welcome, Emily!

Biography:

Jensen began her higher education at a local California community college and went on to receive her Bachelor of Science degree in engineering mathematics & statistics at the University of California Berkeley, and her master's and PhD degrees in electrical & computer engineering at UC Santa Barbara. She has worked as a research and instructional assistant at the California Institute of Technology and has held postdoctoral appointments at UC Berkeley and at Northeastern University.

Research:

Jensen’s research is centered around the analysis and control of spatially-distributed systems, with motivating applications ranging from power systems to satellite constellations to bio-inspired soft-robotics. She develops theory to characterize performance bounds, structural properties, and inherent tradeoffs in these systems as a means to guide controller design and improve system safety and performance. Her work has been recognized by awards including the UC Regents Graduate Fellowship and the Zonta Amelia Earhart Aerospace Engineering Fellowship.

I value the importance that CU �鶹ӰԺ places on quality of teaching and the student experience, in addition to being an institution of world-class research. I am excited to begin a career that combines my passion for working with students along with my love for science. Outside the classroom, I love that �鶹ӰԺ has so many opportunities for hiking with my dog, biking, and enjoying the outdoors!"

The Department of Electrical, Computer and Energy Engineering is welcoming Emily Jensen community. Jensen is joining as an assistant professor in the systems & controls research area, and will begin in spring 2024. Welcome, Emily!

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Combes seeks to transform the quantum technology landscape

Anonymous — Wed, 21 Jun 2023 22:30:15 +0000

Combes seeks to transform the quantum technology landscape Anonymous (not verified) Wed, 06/21/2023 - 16:30

Charles Ferrer

Josh Combes

Quantum technology will open new capabilities in computing, networking and sensing. However, quantum computers that exist today have yet to live up to their full potential.

Assistant Professor Josh Combes is taking the challenge of quantum computing to the next level. Combes, who is based in the Department of Electrical, Computer and Energy Engineering, recently earned a National Science Foundation CAREER Award to further his quantum research and foster the next generation of quantum-aware engineers across disciplines.

Through the CAREER Award, Combes seeks to design qubits — a basic unit of information in quantum computing — that are significantly more reliable than those used today. He calls them second-generation qubits.

While progress has been made on reducing qubit errors, first-generation qubits are designed to perform just below the required error rates.

“There's a huge difference between when the Wright Brothers flew their plane and now when you hop on a Boeing 747. There’s now several generations of aircraft, and the Wright Brothers could be compared to being the prototype of first-generation qubits in quantum,” said Combes.

He also used the example of early computers, which suffered from unreliable components. Over time, technologies such as the transistors have made computers smaller and, more importantly, reliable and faster.

“Second-generation qubits are built very intentionally to be protected against errors and computational noise. To build quantum technology that includes quantum computers, sensors and networks, we need to devise ways to eliminate or protect against those errors,” Combes said.

The development of these low-error, second-generational qubits could accelerate the large-scale superconducting quantum computers’ timeline. Quantum, which requires these large-scale computers, is pushing the boundaries in e-commerce, communications, GPS navigation and national security.

Combes is also committed to building a robust national quantum workforce. Universities around the world are struggling to meet the increased industry demands, which require ample quantum training. To that end, Combes designed a new quantum engineering (QE) minor to help STEM students outside of physics become proficient in quantum.

Quantum technology has traditionally been centered around the work from theoretical and experimental physicists, computer scientists and mathematicians. To create a quantum community, the field will need to draw its expertise across different disciplines.

“We're starting to see people from other fields coming in and making contributions,” said Combes. “We’re seeing electrical engineers, mechanical engineers and chemical engineers starting to make quantum technology, so it’s becoming a more multidisciplinary field.”

CAREER Awards provide approximately $500,000 over five years for junior faculty members “who have the potential to serve as academic role models in research and education and to lead advances in the mission of their department or organization.” Seven faculty members within the College of Engineering and Applied Science have received CAREER Awards from the National Science Foundation in 2023.

“What excites me is how this will impact our graduate students through funding and their ability to work on these ideas for broader impact. That’s the real meaning of earning this CAREER Award.”

Assistant Professor Josh Combes of the Department of Electrical, Computer and Energy Engineering will use a prestigious NSF CAREER Award to further quantum research and foster the next generation of quantum-aware engineers across disciplines.

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Two new faculty members join department for fall 2022

Anonymous — Tue, 27 Sep 2022 14:08:13 +0000

Two new faculty members join department for fall 2022 Anonymous (not verified) Tue, 09/27/2022 - 08:08

Two new faculty members have joined the ECEE team in support of our research and teaching missions. Welcome, Mona and Cody!

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