News

Loomis Laboratory has been awarded a third-place prize in the Energy Conservation Incentive Program of the University of Illinois at Urbana-Champaign. This program, administered by Facilities and Services, both funds and recognizes efforts to reduce energy consumption through facilities upgrades. A plaque commemorating the award will be mounted in the Walnut Hallway. The award comes with a $26,000 prize for additional energy projects.

“We don’t know because no one has tried it,” says Rebecca Holmes, a physicist at Los Alamos National Laboratory in New Mexico. Three years ago, when she was a graduate student at the University of Illinois at Urbana-Champaign, Holmes was part of a team led by Paul Kwiat that showed people could detect short bursts of light consisting of just three photons. In 2016, a competing group of researchers, led by physicist Alipasha Vaziri at Rockefeller University in New York, found that humans can indeed see single photons. Seeing, though, might not accurately describe the experience. Vaziri, who tried out the photon-glimpsing himself, told the journal Nature, “It’s not like seeing light. It’s almost a feeling, at the threshold of imagination.”

Dr. Hong-Yan Shih, a postdoctoral researcher at the Department of Physics and at the Carl R. Woese Institute for Genomic Biology at the University of Illinois at Urbana-Champaign, has been selected for the 2019 Dissertation Award in Statistical and Nonlinear Physics of the American Physical Society (APS). This award recognizes exceptional young scientists who have performed original doctoral thesis work of outstanding scientific quality in the area of statistical and nonlinear physics. Shih will be presented with the award at the APS March Meeting, where she will give an invited talk.

Shih completed her doctoral dissertation titled “Spatial-temporal patterns in evolutionary ecology and fluid turbulence” in 2017 working in Professor Nigel Goldenfeld’s theoretical physics group. It explores “the turbulence of ecosystems and the ecology of turbulence.” In her thesis, Shih reports on three projects at the boundaries of ecology and evolution, analyzed using methods from statistical mechanics, and a fourth project that made a major advance to the important problem of the laminar-turbulent transition of fluids in pipes. This latter problem was first scientifically studied in 1883, and Shih’s contribution arose from an unusual perspective.

Professor Nadya Mason has been elected a Fellow of the American Physical Society (APS) "for seminal contributions to the understanding of electronic transport in low dimensional conductors, mesoscopic superconducting systems, and topological quantum materials."

Mason is an experimental condensed matter physicist who has earned a reputation for her deep-sighted and thorough lines of attack on the most pressing problems in strongly correlated nanoscale physics.

Two University of Illinois faculty members are at the White House in Washington, D.C., today, attending the Advancing American Leadership in QIS Summit.

Quantum Information Science (QIS) and Technology has emerged over the last decade as one of the hottest topics in physics. Researchers collaborating across physics, engineering, and computer science have shown that quantum mechanics—one of the most successful theories of physics that explains nature from the scale of tiny atoms to massive neutron stars—can be a powerful platform for information processing and technologies that will revolutionize security, communication, and computing.

Recently, a team of scientists led by Pablo Jarillo-Herrero at the Massachusetts Institute of Technology (MIT) created a huge stir in the field of condensed matter physics when they showed that two sheets of graphene twisted at specific angles—dubbed “magic-angle” graphene—display two emergent phases of matter not observed in single sheets of graphene. Graphene is a honeycomb lattice of carbon atoms—it’s essentially a one-atom-thick layer of graphite, the dark, flaky material in pencils. 

Researchers at the University of Illinois at Urbana-Champaign have recently shown that the insulating behavior reported by the MIT team has been misattributed. Professor Philip Phillips, a noted expert in the physics of Mott insulators, says a careful review of the MIT experimental data by his team revealed that the insulating behavior of the “magic-angle” graphene is not Mott insulation, but something even more profound—a Wigner crystal.