To request a media interview, please reach out to School of Physics experts using our faculty directory, or contact Jess Hunt-Ralston, College of Sciences communications director. A list of faculty experts and research areas across the College of Sciences at Georgia Tech is also available to journalists upon request.
Rovers tend to be designed like little cars, equipped with wheels that spin on fixed axles. But that can leave the vehicles vulnerable to getting stuck, as Spirit infamously did on Mars. That's why School of Physics Daniel Goldman's team is finding new ways for rovers to move.
GradIO 2019-03-16T00:00:00-04:00Dating back more than 3,000 years, knitting is an ancient form of manufacturing, but Elisabetta Matsumoto of the Georgia Institute of Technology in Atlanta believes that understanding how stitch types govern shape and stretchiness will be invaluable for designing new "tunable" materials. For instance, tissuelike flexible material could be manufactured to replace biological tissues, such as torn ligaments, with stretchiness and sizing personalized to fit each individual. Matsumoto is an assistant professor in the School of Physics.
Katherine Roberts 2019-03-06T00:00:00-05:00Struck by climbing suicide rates, third-year School of Biological Sciences major Collin Spencer organized the first Intercollegiate Mental Health Conference, which kicked off on Feb. 15, 2019. "Mental health is one of the most pressing issues for adolescents in the country right now," Spencer says.
early admit 2 2019-02-20T00:00:00-05:00That's what scientists found while studying the dinnertime of black soldier fly larvae, or maggots. When vast quantities of these larvae feed together, their surging movement around their food creates a living fountain of writhing bodies. That may sound revolting, but the strategy makes maggots uniquely efficient at devouring meals en masse, scientists reported in a new study. [Ear Maggots and Brain Amoeba: 5 Creepy Flesh-Eating Critters] Larvae of the black soldier fly (Hermetia illucens) typically hatch, live and eat together in the hundreds and thousands, and each voracious grub can consume up to twice its body mass in a day, lead study author Olga Shishkov, a doctoral candidate in mechanical engineering at Georgia Tech, told Live Science. Shishkov works with mechanical engineering professor David Hu, who holds concurrent appointments in the Schools of Biological Sciences and of Physics. Story was also covered by Fox News and Science Friday
"Research can always wait. Life is irreplaceable," writes John Wise in his feature for Astronomy behind the scenes of his most recent paper. He's explaining his decision to put his work on hold during his wife's cancer treatment (quoted here). Wise initially set out to answer this question: How do supermassive black holes form in the first place? The feature offers a rare look at the intersection between a researcher's work and his perosnal life. In January, we covered his work on black holes here.
yanni 2019-01-24T00:00:00-05:00
"Even a horse's tail shouts out secrets," says David Hu, who holds joint appointments in the School of Biological Sciences and the School of Mechanical Engineering. For the past few months, Hu had been plagued by a simple question: What's the purpose of a horse's tail? Using biology and engineering, Hu and his team found the answer. Hu is also an adjunct professor in the School of Physics.
work family interactions 2018-10-16T00:00:00-04:00Once more, this ultrapopular story about School of Physics' Dan Goldman's lazy-ant research has been picked up. Maybe we're just really relieved to find out that laziness has some benefits?
campus drone 2018-10-01T00:00:00-04:00Georgia Tech has received an award for $3.7 million from the National Science Foundation to cover 70 percent of the cost of a new high-performance computing (HPC) resource that will be established at the Coda building at Tech Square, which is set to open next spring. Project participants include two from the College of Sciences: David Sherrill, professor of chemistry and biochemistry, and Deirdre Shoemaker, professor of physics.
Brett Aiello 2018-09-11T00:00:00-04:00To revive antibiotics and devise new drug designs, Georgia Tech researchers team up with Oak Ridge’s Titan supercomputer....Knocking out efflux pumps is a promising strategy both to create new drugs and bring old antibiotics back to life, says physicist James C. Gumbart of the Georgia Institute of Technology...Gumbart and his team have used Titan, the Cray XK7 supercomputer at the Oak Ridge Leadership Computing Facility, a Department of Energy (DOE) user facility, to simulate the shape and related stability of proteins related to cells' machinery to expel toxic substances.
jonsson 2018-09-03T00:00:00-04:00Is there a good excuse for laziness? Maybe, if you're in a colony of ants. When they set out to dig a tunnel, only a few of them actually work. The majority just get out of the way. It turns out that their laziness is a key strategy to getting work done efficiently and avoiding traffic jams, found Daniel Goldman of the School of Physics. Find the original Georgia Tech story on his research here and more coverage at Quartz and Popular Mechanics.
John Lewis Student Center 2018-08-17T00:00:00-04:00Ants are renowned for their industriousness. However, new research at Georgia Tech suggests that although ant colonies are very efficient, that may be because 70 percent of them are doing very little — at least when it comes to tunnel digging. Daniel I. Goldman, a physicist at the Georgia Institute of Technology, and his colleagues, found that the secret to efficient tunnel digging by fire ants was that 30 percent of the ants did 70 percent of the work. The work is published in Science. Find more coverage at The Washington Post, ScienceNews and Cosmos.
New evidence has surfaced suggesting that exoplanet Kepler-186f could have changing seasons and a climate, much like Earth. The discovery is exciting astronomers and leading to calls for newer, more detailed studies of this alien world. If Kepler-186f sounds familiar, that's because it's been in the news before: the Earthlike world has been a subject of scientific inquiry since it was first discovered in April 2014, with the help of NASA's Kepler Space Telescope, which revealed it to be an Earth-size planet whose orbit is located within a habitable distance from its sun. A new study published in the Astronomical Journal corroborates the previous findings and suggests there is even more reason to believe it could be an Earth 2.0. Using simulations, authors Yutong Shan and Gongjie Li analyzed the planet's spin-axis dynamics, meaning the relationship between the planet's axis of orbit relative to its orbit around its host star… “Our study is among the first to investigate climate stability of exoplanets and adds to the growing understanding of these potentially habitable nearby worlds,” said Li, an author of the study and assistant professor in the School of Physics.
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Events
In-Person Work at Georgia Tech: Hybrid Town Hall
The campus community is invited to join us for a town hall on Wednesday, May 14, from 10 to 11 a.m. to review the Institute’s phased approach toward a more in-person work model for the 2025-26 academic year.
School of Physics CM/AMO/Quantum Seminar - Dr. Chuankun Zhang
A solid-state nuclear clock using a VUV frequency comb
A solid-state nuclear clock using a VUV frequency comb
The size and complexity scaling of quantum systems from individual trapped ions to tens of thousands of atoms in optical lattices has driven major advances in precision measurement and quantum technology.
Experts in the News
Biofilms have emergent properties: traits that appear only when a system of individual items interacts. It was this emergence that attracted School of Physics Associate Professor Peter Yunker to the microbial structures. Trained in soft matter physics — the study of materials that can be structurally altered — he is interested in understanding how the interactions between individual bacteria result in the higher-order structure of a biofilm
Recently, in his lab at the Georgia Institute of Technology, Yunker and his team created detailed topographical maps of the three-dimensional surface of a growing biofilm. These measurements allowed them to study how a biofilm’s shape emerges from millions of infinitesimal interactions among component bacteria and their environment. In 2024 in Nature Physics, they described the biophysical laws that control the complex aggregation of bacterial cells.
The work is important, Yunker said, not only because it can help explain the staggering diversity of one of the planet’s most common life forms, but also because it may evoke life’s first, hesitant steps toward multicellularity.
Quanta Magazine 2025-04-21T00:00:00-04:00Postdoctoral researcher Aniruddha Bhattacharya and School of Physics Professor Chandra Raman have introduced a novel way to generate entanglement between photons – an essential step in building scalable quantum computers that use photons as quantum bits (qubits). Their research, published in Physical Review Letters, leverages a mathematical concept called non-Abelian quantum holonomy to entangle photons in a deterministic way without relying on strong nonlinear interactions or irrevocably probabilistic quantum measurements.
Physics World 2025-04-09T00:00:00-04:00Peter Yunker, associate professor in the School of Physics, reflects on the results of new experiments which show that cells pack in increasingly well-ordered patterns as the relative sizes of their nuclei grow.
“This research is a beautiful example of how the physics of packing is so important in biological systems,” states Yunker. He says the researchers introduce the idea that cell packing can be controlled by the relative size of the nucleus, which “is an accessible control parameter that may play important roles during development and could be used in bioengineering.”
Physics Magazine 2025-03-21T00:00:00-04:00School of Physics Professor Ignacio Taboada provided brief commentary on KM3NeT, a new underwater neutrino experiment that has detected what appears to be the highest-energy cosmic neutrino observed to date.
“This is clearly an interesting event. It is also very unusual,” said Taboada, spokesperson for the IceCube experiment in Antarctica. IceCube, which has a similar detector-array design as KM3NeT but is encased in ice rather than water, has detected neutrinos with energies as high as 10 PeV, but nothing in 100 PeV range. “IceCube has worked for 14 years, so it’s weird that we don’t see the same thing,” Taboada said. Taboada is not involved in the KM3Net experiment.
The KM3NeT team is aware of this weirdness. They compared the KM3-230213A event to upper limits on the neutrino flux given by IceCube and the Pierre Auger cosmic-ray experiment in Argentina. Taking those limits as given, they found that there was a 1% chance of detecting a 220-PeV neutrino during KM3NeT’s preliminary (287-day) measurement campaign.
This also appeared in Scientific American and Smithsonian Magazine.
Physics Magazine 2025-02-12T00:00:00-05:00Georgia Tech researchers from the School of Chemistry and Biochemistry, the School of Earth and Atmospheric Sciences, and the School of Physics including Regents' Professor Thomas Orlando, Assistant Professor Karl Lang, and post-doctoral researcher Micah Schaible are among the authors of a paper recently published in Scientific Reports.
Researchers from the University of Georgia and Georgia Tech demonstrated that space weathering alterations of the surface of lunar samples at the nanoscale may provide a mechanism to distinguish lunar samples of variable surface exposure age.
Nature Scientific Reports 2025-01-02T00:00:00-05:00Despite the fact that Antarctica is extraordinarily difficult to get to, astronomers love it and have chosen it as the location for the IceCube Neutrino Observatory. What could possibly make such a remote location so desirable for space science that it’s worth all that trouble?
In this article, scientists including Georgia Tech's Brandon Pries from the School of Physics explain why the South Pole is such a hotspot for astronomers. The answer? At the South Pole, you can best view neutrons and neutrinos in space.
Pries compares the benefits of the South Pole to the North Pole. “The North Pole is more difficult because ice coverage there fluctuates,” explains Pries. “There is a foundation of bedrock underneath Antarctica that serves as a solid base for the IceCube instruments.” This bedrock is also why Antarctica is home to the South Pole Telescope, a radio observatory that helped take the first ever photo of a black hole.
Popular Science 2024-09-05T00:00:00-04:00
