Recent recognition of the �������� includes American COuncil of Learned Societies Fellowship, Arnold O. Beckman Postdoctoral Fellowship and Humboldt Award from Alexander von Humboldt Foundation

Assistant professor awarded 2026 ACLS Fellowship��

, assistant professor in the Department of Asian Languages & Literature at the UW, was awarded a 2026 ACLS Fellowship from the American Council of Learned Societies. The fellowship recognizes excellence in humanities and social sciences research and supports scholars whose work is poised to make original and significant contributions to their fields.��Rominger��will be the 2026 ACLS Pauline Yu Fellow.����

“It means a great deal to hold a fellowship in Pauline Yu’s name,” Rominger said. “Her scholarship on Chinese poetics is part of why I do this work.”��

This year, the program awarded more than $3.5 million to 63 scholars selected from a pool of more than 2,000 applicants.��

Rominger specializes in early Chinese literary and intellectual history. His project, “Aurality and the Search for Sound and Meaning in Early Chinese Texts,” examines how sound-based patterning��shaped meaning in early Chinese��philosophical texts, particularly in��writings��from the Warring States period to the Han dynasty.����

Rominger’s research shows how early Chinese thinkers employed the sound of language not only for style but also to build arguments and express complex ideas. The project brings together close readings of ancient texts, historical reconstructions of Old Chinese pronunciation, and computational tools to offer new insight into the relationship between literary form and philosophical thought.

Postdoctoral scholar awarded Arnold O. Beckman Fellowship in Chemical Instrumentation��

, a UW postdoctoral scholar��in��chemistry, was awarded the Arnold O. Beckman Postdoctoral Fellowship in Chemical Instrumentation. The fellowship supports advanced research by postdoctoral scholars in fundamental chemistry and the development and construction of chemical instrumentation.��

The award provides two years of funding, along with an��additional��$200,000 budget to support instrumentation costs.��

With the fellowship, Rebstock will build a new vibrational spectroscopy instrument designed to��observe��chemical reactions as they happen at surfaces. The instrument will allow researchers to see how molecules move and interact in real time, offering insight into surface chemistry that could help improve technologies such as batteries and clean fuels.��

This fellowship provides Rebstock with a rare opportunity to combine instrument development with fundamental chemistry questions. “I’m excited to pursue both and to explore new ways of probing the chemistry that happens at interfaces.” Rebstock said.��

UW researcher receives Humboldt Research Award��

a UW professor of Earth and space sciences,��received a Humboldt Research Award from the Alexander von Humboldt Foundation. The award recognizes internationally leading researchers across all disciplines for their academic record and significant contributions to their fields.��

Each year, the Alexander von Humboldt Foundation grants up to 100 Humboldt Research Awards to researchers from abroad. Awardees receive personal award��money and��are invited to carry out research projects of their��choosing��in cooperation with specialist colleagues in Germany.��

Teng said he was deeply honored by the recognition and grateful to Professor��Harry��Becker, head��of the Geochemistry Group at��FU-Berlin, for��the nomination. The award will allow��Teng��to spend extended periods over the next few years conducting research at Freie University Berlin, beginning with his��sabbatical this��summer.��

“It is a wonderful opportunity to spend extended periods over the next few years conducting cutting-edge research at Freie University Berlin,” Teng said.��

The award will also enable Teng to develop new collaborations across Germany and become part of the Humboldt Foundation’s international network of distinguished researchers.��

Recent recognition of the �������� includes the Camille Dreyfus Teacher-Scholar Award, the Rosentiel Award for contributions to ocean science, and the 2026 Distinguished Community Engagement Award

Assistant professor of chemistry awarded 2026 Camille Dreyfus Teacher-Scholar Award��

, assistant��professor��of��chemistry��at the��UW, received��a 2026 Camille Dreyfus Teacher-Scholar Award from the Camille and Henry Dreyfus Foundation. The award supports early-career faculty in the chemical sciences who have created an outstanding independent body of scholarship and��demonstrated��a strong commitment to education.����

Each Camille Dreyfus��teacher-scholar��receives an unrestricted research grant of $100,000. Golder was one of 17 scholars selected for the 2026 award.����

Golder’s research focuses on the design and reconstruction of plastics, with an emphasis on improving polymer integrity and sustainability. The work explores how chemical design can support stronger, more adaptable materials while addressing broader challenges in plastic waste and long-term environmental impact.��

Golder said the foundation’s support will give his group the flexibility to continue pursuing “the boldest and most exciting ideas” over the next five years.��The��recognition��also��reflects the hard work and creativity of his research group over the past six years, he said.��

Principal oceanographer receives Rosenstiel Award��

, principal oceanographer at the UW Applied Physics Laboratory��and affiliate��assistant��professor��at the School of��Oceanography, received the��2026 Rosenstiel Award. The award, created in 1971 by the Rosenstiel Foundation, honors mid-career scientists whose work has made significant and growing impacts in their fields.����

The award is presented each year on a rotating basis across marine geosciences, atmospheric sciences, marine biology and ecology, ocean��sciences,��and environmental science policy. Whalen was invited to present a lecture at the University of Miami Rosenstiel School of Marine,��Atmospheric,��and Earth Science, where the award was presented in April.����

Whalen studies small-scale physics��in the ocean, including processes that generate turbulence��and mix the water, along with how these processes��interact with the dynamics of the water across ocean basins. Her work helps scientists better understand the physical drivers that shape climate and marine environments.��

Whalen said she was honored to receive the award and to join the ranks of oceanographers whose work she admires. Receiving the award also gave Whalen the opportunity to visit the Rosenstiel School, where she met with faculty and students and learned more about their work.

Professor receives Distinguished Community Engagement Award��

,��professor of ethnic, gender and labor studies and American Indian studies and adjunct professor of education at UW Tacoma��received the 2026 Distinguished Community Engagement Award in the project category. Montgomery is also an adjunct professor of bioethics and humanities at the UW School of Medicine.��The award recognizes her leadership of the Indigenous Speaker Series and Community Engagement: Promoting Indigenous Knowledge Systems and Multigenerational Community Learning.��

Through support for the Haida Sails Resurgence Project and the Northwest Maritime Center, Montgomery’s work has created meaningful opportunities for co-learning, cultural��exchange,��and the uplifting of Indigenous Knowledge Systems through place-based and multigenerational learning experiences.��

Montgomery’s community-engaged scholarship focuses on amplifying Indigenous voices, supporting dialogue around cultural and traditional lived experiences and strengthening partnerships that connect academic spaces with community knowledge. The Indigenous Speaker Series, which Montgomery created in 2015, has become a platform for sharing place-based Indigenous��knowledges��and expanding conversations across communities.����

“As a visitor to the Pacific Northwest, it is an honor to continue the responsibility to uplift place-based Indigenous��knowledges��and nurture the reciprocity of community partnerships,” Montgomery said.��

Three �������� faculty members��have been elected to the American Academy of Arts and Sciences. Their work spans environmental science,��computing��and engineering, addressing challenges ranging from climate resilience and ecosystem sustainability to artificial intelligence and accessible healthcare technologies.��

Founded in 1780, the����recognizes leaders across disciplines whose work advances research, public policy��and the common good. The Academy elects��roughly 250��members each year.��

,��UW��professor��in��the School of Aquatic and Fishery Sciences, was��elected��for research on how climate change,��urbanization, and��land use affect freshwater ecosystems and fisheries.��

Schindler’s work focuses on salmon habitats, watershed health��and ecosystem resilience in Alaska and the Pacific Northwest, helping scientists better understand how environmental change affects ecosystems, wildlife��and communities that rely on fisheries.��

“I’m deeply honored by the recognition,” Schindler said. “I’m also grateful for the colleagues and students at the UW whose��curiosity��and camaraderie have made our science impactful and genuinely fun.”��

,��professor of computer science and engineering and��director of the Allen��School,��was elected��for��contributions to data management and data science,��as well as her leadership roles at UW and nationally.��

Balazinska��develops data management systems and techniques��to help users across domains process complex and large datasets more efficiently and more easily, including tabular data, images and videos,��content��generated by��artificial intelligence,��and scientific datasets. Her work has included systems for cloud analytics, stream��processing, and video��analysis��among others.������

Balazinska��said joining the Academy��shows��how far science and engineering have come, while also��highlighting future��opportunities that will��arise as AI reshapes research and discovery.��

“AI has the potential to accelerate progress in ways I couldn’t have imagined at the start of my career,” she said.��

, professor in the��Allen School��and the��Department of Electrical & Computer Engineering, was��elected��for research in ubiquitous computing, human-computer��interaction��and sensor-enabled systems.��

Patel develops technologies that use smartphones,��sensors��and machine learning to expand access to healthcare and improve sustainability. His work includes smartphone-based health screening tools designed to improve access to care, as well as technologies that help households��monitor��energy and water use more efficiently.��

Several technologies developed by Patel and his students have been commercialized through startups and later adopted by major companies, including Google.��

Patel said he was “humbled and honored” by the recognition and��wants it to encourage��broader thinking about the role of applied computing research.��

“I hope this serves as a catalyst for others to embrace a broader, more practical perspective on what computing can achieve for society,” he said.��

�������� professor of physics and UW research professor emeritus are part of an international team that won the 2026 . The $3 million award is shared among roughly 400 scientists, including 18 other researchers from the UW team. It celebrates decades of work to better understand the muon — a subatomic particle with anomalous properties. This collaborative effort could ultimately lead to the discovery of entirely new particles.

“A remarkable aspect of these experiments is that it took the collective talents and experience of scientists and engineers from particle, nuclear, atomic, optical, accelerator and theoretical physics communities to work coherently toward one single goal,” Hertzog said. “Together, we measured a property of the muon that encapsulates almost everything we know about modern physics from relativity to quantum mechanics to the zoo of particles that govern the fundamental forces that shape our world.”

The were established in 2012 to recognize research achievements in life sciences, fundamental physics and mathematics.��

Muons, short-lived subatomic particles, are created for experiments by particle accelerators. They exist for a fraction of a second before decaying into electrons and even tinier particles called neutrinos. During their short life, muons exhibit magnetic properties that deviate slightly from the – the leading theory that describes the particles and forces that make up the universe, along with anything that exists that has not yet been discovered.

The experiments recognized by the Breakthrough Prize represent 60-plus years of work to find out exactly how far the muon’s magnetism strays from Standard Model predictions. The first experiments began in 1959 at the, also called CERN.��

Hertzog’s group at the University of Illinois was involved in a later experiment at the in the mid-1990s. He joined the faculty at UW in 2010 and helped develop a new experiment at (Fermilab) that in 2025 with record-setting precision.��

While Hertzog and others have now completed their experimental measurements, theorists�� continue to refine the predictions of the Standard Model. In time, the gap between theory and experiment — where the muon currently hovers — may vanish or persist. If the muon’s properties never fit the Standard Model, physicists may need to explore entirely new theories.��

“No matter where the final theory settles, the comparison with our experiment will have important consequences and give us deep insight into the heart of matter,” Hertzog said.

Many UW physicists have been recognized by Breakthrough Prizes since the prizes’ inception, including a banner year in 2021 that also featured a win in the life sciences category by Nobel Prize laureate , a UW professor of biochemistry.

“The Breakthrough Prize has previously recognized UW physicists for work that deepened our understanding of gravity, dark energy and dark matter,” said , UW divisional dean of natural sciences in the College of Arts and Sciences. “This latest recognition is a testament to the value of large-scale collaborative physics research and we are very proud of the accomplishments of all of the UW faculty, postdocs and students who contributed to this effort.”

A full list of current UW researchers recognized by the 2026 prize . Learn about other UW wins at the Breakthrough Prize here.��

For more information, contact Victor Balta at balta@uw.edu.

The Ecological Society of America on Wednesday awards. , a �������� assistant professor of environmental and forest science, was named an Early Career Fellow, which recognizes scientists for contributions to advancing and applying ecological knowledge within eight years of completing a doctorate.

Willing studies how microbes respond, and help plants cope with, environmental change. focuses on fungi and other microbes living near plant roots. Much like the gut microbiome, these communities play a critical role in plant nutrition, immune function and overall forest health.

Willing’s lab focuses on understanding these communities and how they are shifting with climate change. Her research integrates methods from various scientific disciplines to gain insight into the ecosystem-wide impact of fungi.

“I work across pretty diverse fields, from fungal ecology to plant and forest ecology,” Willing said. “Integrating everything together is challenging, but I think it’s a critical intersection to study right now and this award is a nice acknowledgement of that.”

As a Faculty Fellow, Willing also collaborates with federal, state and tribal agencies to incorporate fungi into climate adaptation planning.

Many of her lab’s projects examine responses to climate change. For example, one of Willing’s current grad students is studying fungi in post-fire ecosystems.

Some fungal groups are fire-adapted, meaning that they can withstand wildfire better than others. After wildfire, the soil often becomes hydrophobic, which causes water to run off the surface instead of soaking in. This increases the risk of erosion, among other consequences. Fungi help seedlings to establish and stabilize the soil by helping it retain water.

Early findings from her lab indicate that prolonged fire suppression, a stewardship strategy intended to minimize wildfire impacts, can limit microorganisms fire tolerance, which then exacerbates the damage caused by a fire.

“There are lots of different nuances that we’re really just starting to understand,” Willing said.

She hopes this work can help inform future forest management practices. Although there are many mushroom enthusiasts in the Pacific Northwest, Willing is one of few scientists in the region studying how these organisms fold into broader ecosystems.

Most of the data on microbial communities was collected within the past 20 years or so, which makes it difficult to gauge how these organisms are responding to climate change. Another project in Willing’s lab involves conducting genetic analyses on preserved plant specimens to establish a baseline for fungal health.

“Our understanding of what fungal and bacterial communities were like before the onset of rapid warming is really limited,” Willing said.

Building this baseline will help researchers see how microbial communities are evolving and reveal management opportunities.

Without fungi, life on Earth couldn’t exist as we know it. Dead logs and fallen leaves would simply accumulate, with nothing to break them down and return their nutrients to the soil.

“Fungi are involved in everything,” Willing said. “In the cycle of life, they are at the beginning, helping plants to take root across every ecosystem on Earth, and at the end, helping to create lush soils for future life to flourish.”

ESA will acknowledge and celebrate fellows during a ceremony on July 27 at the annual meeting in Salt Lake City. Early Career Fellows are elected for five years.

For more information about her work, contact Willing at willingc@uw.edu.

Affiliate professor of biology receives 2026 Kenneth S. Norris Lifetime Achievement Award��

, a research scientist and affiliate professor in the in the Department of Biology at the ��������, was honored with the ��from the��. The award recognizes exemplary lifetime contributions to science and society through research, teaching, and service in marine mammalogy.��

Over a 40-year career, Moore’s research has focused on cetacean ecology, acoustics, and natural history, particularly in the Arctic. A prolific researcher, she is widely recognized as a pioneer in using marine mammals as ecosystem sentinels in this rapidly changing region. Over decades of studying whales, Moore has helped scientists understand the health of ocean environments and how they are changing over time. Her work provides critical insight into the impacts of climate change in the Arctic and how marine ecosystems are responding. Her contributions to Arctic science have also been recognized with the����from the International Arctic Science Committee and the 2023����from the Alaska SeaLife Center; she is also a science adviser to the Washington State Academy of��Sciences,��and was appointed Commissioner��of the�� in 2022.

Natt-Lingafelter professor of chemistry awarded 2026 Earle K. Plyler Prize��

,��professor of chemistry at the UW,��was��awarded the 2026�� from the American Physical Society for her impactful contributions to the anharmonic vibrational spectroscopy and dynamics of molecular radicals, ions, and clusters. Established in 1976, the prize honors pioneering spectroscopist Earle K. Plyler and is sponsored by the Journal of Chemical Physics. The prize will be presented at the APS Global Physics Summit, the world’s largest physics research conference, in March 2026.

McCoy’s research focuses on theoretical chemistry, where she develops methods to understand how molecules move, vibrate, and exchange energy. Her work has helped scientists better understand the fundamental behavior of molecules—providing insight into how chemical reactions occur and how energy flows through molecular systems. Much of her recent work has focused on hydrogen-bonded systems and, specifically, proton transport. She is also interested in exotic molecules, like CH5+ and H5+, which have been proposed to exist in the interstellar medium. These advances help lay the groundwork for progress in areas ranging from atmospheric chemistry to materials science.

UW joint professor of mathematics and computer science awarded inaugural Trevisan Prize��

�������� professor ��has received the�� for his breakthrough contributions to the study of optimization problems.��Rothvoss��holds joint appointments in the Department of Mathematics and the Paul G. Allen School of Computer Science and Engineering and was honored in the mid-career category—a recognition of his impactful work over the course of his career.

for outstanding work in the theory of computing is sponsored by the Department of Computing Sciences at Bocconi University and the Italian Academy of Sciences. Awardees receive a one-time monetary prize and a medal and are invited to give public lectures at Bocconi University. The award ceremony and lectures took place in January 2026.

Rothvoss��has built a distinguished record of contributions to theoretical computer science and discrete optimization. He shares that “over the years my focus has changed a bit…I worked on approximation algorithms, which deal with finding provably good solutions to NP-hard problems in polynomial time.” His work has since shifted toward discrepancy theory and the theoretical foundations of linear and integer programming.��In simple terms,��Rothvoss��studies��the mathematics��behind making��optimal��decisions��in��highly complex��systems. His research helps reveal when efficient solutions are��possible and optimization problems can be solved.��

Political��science��professor��receives John Gaus Award��

,��professor of��political��science at the UW,��received the����from the American Political Science Association��(APSA).��

The John Gaus Award is presented annually to honor a lifetime of exemplary scholarship in the joint tradition of political science and public administration. Prakash was selected unanimously for the award in recognition of a career devoted to advancing scholarship at the intersection of political science and public administration. A nomination letter noted that Prakash’s research, particularly on environmental issues, has helped bring environmental concerns into public administration in a variety of ways, including examining how businesses and NGOs can fill governance gaps. At the same time, the letter highlighted how his work explores the risks of these nontraditional governance mechanisms, including potential issues such as regulatory capture and accountability deficits.��

Prakash’s research spans environmental governance, public policy, and global political economy. Over the course of his career, he has published eight scholarly books and more than 130 articles in peer-reviewed journals, with his work cited more than 18,000 times across the field. As part of the honor, Prakash presented the Gaus Lecture at the APSA Annual Meeting in September 2025.

Washington Sea Grant��interim��director��receives��governor’s��leadership��award��

, interim director of Washington Sea Grant, received the��, which recognizes exemplary leadership and service to the state of Washington.

Little was honored for her work supporting the state’s coastal communities through Washington Sea Grant’s research, outreach, and partnership-driven initiatives.��

Little has dedicated more than 15 years to strengthening Washington’s coast through strategic vision, inclusive practices, and sustained investment in community-centered programs. Under her leadership, Washington Sea Grant delivered nearly $250 million in services and economic benefits statewide between 2021 and 2024, reflecting the program’s broad impact across coastal and maritime communities.��

“A big thank you to the team at Washington Sea Grant for the nomination,” Little said.��“I’m��deeply grateful to work alongside such thoughtful colleagues, who are so dedicated to our shared work.��I’m��so honored by this recognition from the��governor. This award really is a testament to the impact of Washington Sea Grant’s work in serving the state’s coastal communities.”

Biology��professor��awarded Rome Prize Fellowship in Environmental Arts & Humanities��

, professor of biology��at��the UW,��was awarded��the prestigious in the new Environmental Arts & Humanities category by the��. This pilot fellowship supports collaborative projects that explore how human beings relate to, experience, and interpret the natural world.

In partnership with Katharine Ogle, lecturer��of��English at��the University��of Southern California, Summers will pursue a project titled��“Piscis Romana.”��Their work draws on��natural history��research conducted at the Friday Harbor Laboratories to investigate the links between marine life,��ecology,��and poetic expression.��

“This��award will allow��Katie Ogle and��me to��further explore the links between poetry and natural history that have been developed by a group of us at Friday Harbor Labs,”��Summers said.��

Summers’ biological research spans marine and aquatic systems with a strong emphasis on understanding organismal form,��function,��and the broader natural-history context in which��species��evolve and interact. Partnering��with Ogle, he will extend that scientific inquiry into the realm of arts and humanities, looking at how the natural world inspires literary forms,��metaphors,��and cultural narratives.��

With this Rome Prize fellowship, Summers joins a competitive cohort selected from��nearly 1,000��applicants and will spend several��months in��residence at the Academy in Rome, working among scholars and artists from around the world.��

The Royal Swedish Academy of Sciences on Oct. 8 to Susumu Kitagawa, Richard Robson and Omar M. Yaghi “for the development of metal–organic frameworks,” or MOFs.

These materials are made up of a repeated network of molecular building blocks that form a crystalline structure that has large pores in it. MOFs are incredibly modular, which means they can be used for a seemingly endless variety of applications, including harvesting water from desert air or removing toxic chemicals from a solution.

Both , a �������� associate professor of chemistry, and , a UW assistant professor of chemistry, use MOFs in their research at the UW. UW News reached out to them to learn more about the significance of these structures and how researchers use them.

Can you explain what a MOF is?

Dianne Xiao: MOFs are materials composed of metal ions — we call these the “nodes” — connected by rigid organic bridging groups — we call these the “struts.”�� Together they make an extended, crystalline porous network.

There are many different analogies that people have used to explain MOFs to a general audience. One common description is a “crystalline sponge,” which highlights how MOFs have very large interior surface areas and void spaces that can be used to bind and store specific molecules, what we call “guests.”

Another phrase people have used is “molecular tinker toys,” which highlights how tunable and modular the synthesis is: You can pair virtually any metal ion on the periodic table with hundreds, if not thousands, of different organic bridging groups, and obtain a MOF with properties tailored to your specific application.

What kind of chemistry do they help facilitate?

Douglas Reed: The modularity of MOFs allows researchers to design materials to soak up a specific guest molecule, and the immensely high surface areas enable MOFs to remove large quantities of these guest molecules very quickly. One example is removing carbon dioxide from industrial waste streams: This application requires a material that can selectively soak up carbon dioxide, but leave behind benign molecules, such as nitrogen and water. MOFs can do this with greater selectivity, higher carbon dioxide removal capacity and lower energy penalties than traditional technologies.

In another example, MOFs with different organic struts and metal nodes can be used to remove forever chemicals, such as PFAS, or toxic chemicals, such as heavy metals, from water.

Other researchers use the high surface area of the pore to more effectively store large quantities of gasses, such as hydrogen, that can be used as clean fuels. People can even place catalytic sites within the pores to perform challenging chemical reactions.

What is the significance of the discovery that was awarded this year?

DX: We already have some porous materials, such as activated carbon, mesoporous silica and zeolites, which play incredibly important roles in industry and in our daily lives. But compared to these traditional porous materials, what makes MOFs distinct and significant is their molecular tunability and structural diversity.

As the , since Kitagawa, Robson and Yaghi’s foundational work in the 1990s, tens of thousands of MOFs have been synthesized and discovered. Some of these MOFs have already been commercialized for applications, such as carbon dioxide capture and toxic gas storage. However, regardless of commercialization potential, the field of MOFs has been and will continue to be a very exciting field for basic science, thanks to their tunability!

Can you talk about how you use MOFs in your research at the UW?

DX: Porous materials, and MOFs specifically, are central to my group’s research. One area is heterogeneous catalysis, where we take advantage of the tunability of MOFs to create active sites that make it easier for chemical reactions to happen than they would on their own. We’re also very interested in making porous materials that can conduct electricity for applications such as electrochemical carbon dioxide capture and electrocatalysis.

DR: While our research group doesn’t study traditional MOFs, we use MOF-based concepts to make existing materials porous. With this extra space, we can potentially make more stable solar cells by introducing repair molecules. Similarly, we can increase the efficiency of cooling devices by providing better airflow through the material. Many foundational synthetic methods for our current research are based on existing metal–organic frameworks.

For more information, contact Xiao at djxiao@uw.edu and Reed at dreed4@uw.edu.

The Royal Swedish Academy of Sciences on Tuesday awarded the 2025 jointly to , and , “for the discovery of macroscopic quantum mechanical tunneling and energy quantization in an electric circuit.”

Clarke, a professor emeritus of physics at the University of California, Berkeley, collaborates with the at the ��������. ADMX scans for evidence of dark matter from beneath the Seattle campus, in a cold dark box surrounded by a powerful magnetic field. The experiment is managed by the U.S. Department of Energy’s and it hinges on technology designed by Clarke.

“I was elated upon hearing the news about John. Simply elated,” said , a UW professor emeritus of physics and lead scientist at ADMX.

The three laureates were recognized for that captured two quantum mechanical properties at the visible scale. Clarke’s brainchild, which caught Rosenberg’s attention 25 years ago, is a Superconducting Quantum Interference Device, or SQUID, which can make ultrasensitive measurements.

“John Clarke first got involved with ADMX around 2000,” Rosenberg recalled. “To this day, he remains a much-loved ADMX collaborator.”

The relationship began when ADMX organized a workshop at Lawrence Berkeley Laboratory to brainstorm solutions to a technical issue the researchers had encountered. The way the experiment searches for dark matter is akin to a radio searching for a station, but instead of music, it is looking for axions — the particles theorized to make up dark matter.

Detecting axions requires amplifying very, very quiet microwaves. At the time, the group only had access to noisy electronic amplifiers, which were drowning out the very signal they sought to capture. At the workshop, Clarke presented a SQUID amplifier as a potential solution.

“We considered all kinds of alternative technologies, but none fit the bill,” Rosenberg said. “The SQUID amplifiers were indeed the breakthrough we needed.”

Clarke joined ADMX and brought the amplifiers with him. , a UW professor of physics and co-spokesperson for ADMX, was a postdoc at the time.

“The SQUID amplifiers gave us the sensitivity necessary to do a search,” Rybka said. “We’ve been operating for years and years and have only explored a fraction of the space, but we couldn’t have even started without these amplifiers.”

ADMX is still using an iteration of Clarke’s original amplifier, improved upon by his students over the years. Still, the “big transition,” was moving to the SQUID amplifier, and that is just one example of how this technology can revolutionize an experiment.

“The laureates moved the field of particle physics from classical measurement to quantum sensing,” Rybka said. “It makes stuff that used to just be on the blackboard — quantum mechanics — experimentally accessible and even useful. In my opinion, you wouldn’t have modern quantum computers without the work done by this group.”

The Nobel Assembly at the Karolinska Institute on Monday jointly to — an alum of the �������� — along with Frederick J. Ramsdell and Shimon Sakaguchi “for groundbreaking discoveries concerning peripheral immune tolerance that prevents the immune system from harming the body.”

Brunkow is a senior program manager at the , and received her bachelor’s degree in molecular and cellular biology from the UW in 1983. Brunkow went on to .

Brunkow’s award-winning research comes from when she was working with Ramsdell at Celltech Chiroscience in Bothell, Washington. The two researchers identified a mutation in a gene called foxp3, which makes mice susceptible to a type of skin disorder. Mutations in the human equivalent of the foxp3 gene are also responsible for , which has symptoms including intestinal problems, diabetes and scaly, itchy skin.

Sakaguchi later described the role of the wild-type��foxp3��gene in the development of certain white blood cells known as regulatory T cells. These cells, which Sakaguchi discovered, keep other T cells from mistakenly attacking normal tissues. Regulatory T cells also call a cease-fire once the body gets an infection under control.

These findings provided insights into the concept of “peripheral immune tolerance,” which keeps the immune system in check by avoiding autoimmune responses that can damage healthy tissues. The field, which was honored by this year’s Nobel Prize, holds promise in advancing therapies for cancers and autoimmune diseases, and for improvements in treatments to reduce transplant rejection.

Brunkow did not immediately know that she had been awarded the Nobel Prize. She only found out when the family dog alerted them to someone at their door this morning — it was an .

Brunkow is the sixth UW alumnus to win a Nobel Prize after Jeffrey C. Hall, George Hitchings, George Stigler, Martin Rodbell and Linda B. Buck. Hitchings, Stigler and Buck all earned their bachelor’s degrees from UW, graduating in 1927, 1931 and 1975, respectively. Rodbell and Hall earned their doctoral degrees from UW in 1954 and 1971, respectively.

The previous Nobel prize for a scientist working in Seattle went to David Baker, professor of biochemistry at the UW School of Medicine and director of the UW Medicine Institute for Protein Design. .

Recent recognition of the �������� includes an AIS Early Career award, the Tomassoni-Chisesi prize for contributions to theoretical physics and the National Science Foundation CAREER award.

Foster School’s Mingwen Yang receives AIS early career award

, UW assistant professor of Information Systems and Operations Management in the Foster School of Business, received the from the Association for Information Systems.

is a leading international organization dedicated to advancing the practice and study of information systems. Established in 2014, the award recognizes exceptional early-career scholars who have made outstanding contributions to research, teaching and service in the field of information systems, both locally and globally.

A 2024 recipient, Yang was honored for her impactful early work and dedication to advancing the discipline through scholarship and education.

“I am deeply honored and grateful to receive the Association for Information Systems (AIS) Early Career Award, a meaningful milestone in the early stage of my academic journey,” said Yang.

David Kaplan awarded Tomassoni-Chisesi Prize for advances in theoretical physics

, UW professor of physics, received the for his contributions to theoretical physics. Awarded by Sapienza University of Rome, the prize — worth approximately $45,000 — was presented on March 18, 2025 by Giorgio Parisi, recipient of the 2021 Nobel Prize in Physics.

Kaplan was recognized for solving a long-standing problem in physics: — those that exhibit handedness, meaning they behave differently when left- or right-handed — on a computer. His domain wall approach, which adds a fifth dimension to lattice simulations, has become a foundational tool in particle physics.

Reflecting on the personal significance of the recognition, Kaplan shared that the breakthrough has been decades in the making. “I first heard about the problem in 1981 when visiting Princeton,” he said. “Nobel laureate David Gross described it, and I didn’t really understand it then — but filed it away in my mind as something interesting.” That early spark led to a 1992 theory involving a five-dimensional model with two surfaces. It wasn’t until 2019, however, that he saw how a single-surface geometry — like a doughnut or sphere — could yield particles with the same interactions observed in nature, including the weak force. “The jury is still out … but I feel that I am on the right path now and it is very exciting.”�� When asked of his plans for the prize money, Kaplan shared his plans to donate to the UW Department of Physics — “which made the work possible.”

For such an incredible breakthrough, we asked what keeps him motivated to keep exploring such big, complex questions in physics. Kaplan’s answer was simple: “I don’t need motivation to think about complex questions in physics,” he said. “I do it in the shower, as I walk to work, and in my sleep… I find it all obsessively interesting and fun.”

Marchand Receives $800K NSF award to advance synthetic DNA research

, UW assistant professor of chemical engineering, received a from the Division of Molecular and Cellular Biosciences, Systems and Synthetic Biology Program.

The is the agency’s most prestigious honor for early-career faculty, recognizing those with the potential to become academic leaders in both research and education.

With this award, Marchand’s lab will develop sequencing technologies capable of precisely reading and interpreting semi-synthetic DNA alphabets — genetic systems that use more than the four natural DNA bases found in all known life. In other words, while natural DNA uses a four-letter code (A, T, C, G), Marchand’s group is exploring the implications of expanding that alphabet to six letters. Their research aims to understand what happens to biological systems when the genetic code is fundamentally altered.

“Life evolved to use a four-letter DNA alphabet,” Marchand said. “How much of biology breaks versus works when we change that alphabet to six letters is unknown. New technology is required to investigate these questions, which we will develop with this award.”

Marchand said he’s proud of the recognition for his lab’s “bold vision in engineering biology for compatibility with expanded genetic alphabets.”