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.
Comet Lulin, a rare green comet discovered in 2007, is set to make its closest approach to the Earth around Feb. 24. The comet's green color comes from the gases that make up its atmosphere. Its closest approach to Earth will be 38 million miles. James Sowell, principal academic professional in the School of Physics and director of the Georgia Tech Observatory, joins Atlanta News First to talk about the best times to view the comet, where it may have originated, and how rare green comets are in the universe.
Green comet will pass by Earth this month 2023-02-01T00:00:00-05:00Elisabetta Matsumoto, an associate professor in the School of Physics, will present “Knotty Knits: A Chat about Math and Crafts” beginning at 3 p.m. March 3, at Southern Illinois University's Guyon Auditorium. Matsumoto, whose research interests include soft condensed matter physics and the geometry of materials, uses knitting to illustrate the math and mechanics within the craft, and how studying the physics of knitting could lead to applications such as wearable electronics.
SIU’s Tenney lecture to focus on interdisciplinary teaching of math, art and science 2023-01-27T00:00:00-05:00Pushing a shovel through snow, planting an umbrella on the beach, wading through a ball pit, and driving over gravel all have one thing in common: They all are exercises in intrusion, with an intruding object exerting some force to move through a soft and granular material. Predicting what it takes to push through sand, gravel, or other soft media can help engineers drive a rover over Martian soil, anchor a ship in rough seas, and walk a robot through sand and mud. But modeling the forces involved in such processes is a huge computational challenge that often takes days to weeks to solve. Now, engineers at the Massachusette Institute of Technology and Georgia Tech have found a faster and simpler way to model intrusion through any soft, flowable material. Daniel Goldman, Dunn Family Professor in the School of Physics, joined MIT researchers for this project.
How to push, wiggle, or drill an object through granular material 2023-01-19T00:00:00-05:00This roundup of news items includes a report updating research on graphene, a possible successor to silicon as the foundation for all electronics, from Walter de Heer, Regent's Professor in the School of Physics. De Heer's latest advance involves developing a new nanoelectronics platform based on graphene. The technology is compatible with conventional microelectronics manufacturing, a necessity for any viable alternative to silicon. In the course of its research, de Heer's team may have also discovered a new quasiparticle. Their discovery could lead to manufacturing smaller, faster, more efficient, and more sustainable computer chips, and has potential implications for quantum and high-performance computing.
Around the Web: Marketing Muster. Creating Crayons. Joe’s Journalism. Going Graphene. Feather Photography. Car Colors. Checking Chuckling. Fish Fiasco. 2023-01-06T00:00:00-05:00Is science better when it disrupts or when there are just incremental improvements to previous knowledge? The topic was analyzed in a recent study, and it seems that researchers have spent these past years improving things rather than trying to revolutionize everything. The study suggests that the level of "disruptiveness" in scientific research has gone way down in the 2000s compared to the last half-century. Yian Yin, a computational social scientist at Northwestern University in Evanston, Illinois, highlights how disruptiveness is not inherently good, and incremental science is not necessarily bad. Yin cites the first direct observation of gravitational waves, a landmark discovery that was both revolutionary and the product of incremental science. Georgia Tech researchers, many from the School of Physics, worked with researchers at the Laser Interferomoter Gravitational Wave Observatory (LIGO) on the gravitational wave observations. (This coverage also appeared in Nature and Inside Higher Education.)
Science isn't as disruptive as it used to be. Now we need to understand why 2023-01-05T00:00:00-05:00Skipping a stone across water requires skill and patience and, of course, a great stone. Personal preference may send you to a flat, light one, which seems to skip easier. But scientists have found that is not the only way to get impressive leaps. A recent University of Bristol study researched how shape and mass affect the way objects interact with water. And it found that a heavier rock with a good curve — imagine the shape of a mango but smaller — can get an impressive bounce. David Hu, a professor with the School of Biological Sciences and the George W. Woodruff School of Mechanical Engineering, and an adjunct professor in the School of Physics, did not take part in the study but comments on how surprised he was that the Bristol scientists studied curved objects.
Heavier, curvy stones can give surprising results in skipping, physicists say 2023-01-05T00:00:00-05:00Henry Segerman, a British American mathematician and mathematical artist at Oklahoma State University, has invented a puzzle to help explain the Earth's annual trip around the sun: Continental Drift, a 3-D sliding puzzle that made its debut earlier this year. The underlying geometric concept is holonomy: When you travel a loop on a curved surface and return to the starting point, you arrive somewhat turned around, rotated, perhaps by 180 degrees. It's just one of Segerman's inventions that help visualize mathematics. A few years ago, Dr. Segerman demonstrated Extensors: a construction kit for making extending mechanisms from scissor-like hinged parts. Sabetta Matsumoto, an associate professor in the School of Physics, applied mathematician, and Dr. Segerman’s partner, gave input into the contraption’s development and came up with the name Extensor. Between them, math is “a pretty common conversation,” said Matsumoto, who was featured in a 2019 New York Times story about her project to investigate the mathematics and mechanics of knitting. (This story also appears in Yahoo! News.)
A New Puzzle Turns Earth Into a Rubik’s Cube, but More Complex 2023-01-01T00:00:00-05:00In this episode of the Talk Nerdy podcast, host Cara Santa Maria is joined by Feryal Özel, professor and chair of the School of Physics. They talk about her incredible career as a theoretical astrophysicist, her important work on the recent imaging of a black hole with the Event Horizon Telescope (EHT) Collaboration, and the critical need for representation in science.
Black Hole Astrophysics w/ Feryal Özel 2022-12-19T00:00:00-05:00The Artemis 1 mission to the Moon, launched from Kennedy Space Center on Nov. 16, did not have astronauts on board. It did have what NASA is calling "moonikins" — dummies wearing special spacesuits that will measure data on vibration, acceleration, and cosmic radiation. Thomas Orlando, professor in the School of Chemistry and Biochemistry, and an adjunct professor in the School of Physics, will study that data. Orlando is also the principal investigator for Georgia Tech's REVEALS (Radiation Effects On Volatiles And Exploration Of Asteroids And Lunar Surfaces), which will help NASA design the next generation of spacesuits and astronaut habitats.
How Artemis rocket launch will prepare astronauts to head back to moon 2022-11-19T00:00:00-05:00Scientists with the IceCube Neutrino Observatory in Antarctica have now analyzed a decade's worth of such neutrino detections and discovered evidence that an active galaxy called Messier 77 (aka the Squid Galaxy) is a strong candidate for one such high-energy neutrino emitter, according to a new paper published in the journal Science. It brings astrophysicists one step closer to resolving the mystery of the origin of high-energy cosmic rays. The IceCube international collaboration of scientists includes Ignacio Taboada, professor in the School of Physics who also serves as IceCube's spokesperson. (Coverage of this story also appears at Space.com, MSN.com, the Wall Street Journal (registration required), Phys.org, CNET, SciTechDaily, and Inverse.)
IceCube neutrino analysis pegs possible galactic source for cosmic rays 2022-11-04T00:00:00-04:00Most people may think of bacteria, regardless of species and shape, as a single cell, or maybe several free-living cells. The problem with this image, according to microbiologists, is that it doesn’t reflect how most bacteria are likely to live. Often, bacteria use sticky molecules to anchor themselves to a surface, growing in collectives called biofilms. A new study shows that even bacteria floating in the open ocean, which lack an anchoring point for forming large conglomerates, exist in multicellular forms. The study builds on 2021 published research from Georgia Tech scientists that showed unicellular yeast forming multicellular clusters. The School of Biological Sciences researchers include Ozan Bozdag, research scientist; William Ratcliff, associate professor; Kai Tong, Ph.D. Quantitative Biosciences student, and Penelope Kahn. School of Physics researchers involved include Peter Yunker, assistant professor; Thomas C. Day, graduate student; and Seyed Alireza Zamani-Dahaj, Ph.D. student.
Ocean Bacteria Reveal an Unexpected Multicellular Form 2022-11-02T00:00:00-04:00Retired engineer Tom Crowley proves that you can play around with a hobby you love and see it grow into something extraordinary. The 80-year-old has turned his love of astronomy into consulting work with Georgia Tech's Aloha Telescope outreach program. He operates the robotic telescope on Maui through high-speed internet connections from his home in Stone Mountain. Crowley works in partnership with James Sowell, principal academic professional and astronomer in the School of Physics, and director of the Institute's observatory. Together, they’re bringing live video images of the moon into Georgia K-12 classrooms. (More information is available at the Georgia Tech Research Institute’s Direct to Discovery outreach program website, which is creating a Zoom option so that multiple schools can participate at the same time.)
Georgia Tech’s Aloha Telescope brings thrilling images to K-12 classrooms 2022-11-01T00:00:00-04:00- ‹ previous
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Events
School of Physics Spring Colloquium Series-Dr. Lia Medeiros
Lia Medeiros(Univ. of Wisconsin Milwaukee) EHT images of black holes: what we've learned from them and how we can improve them
Systems Matter Seminar | Materials-Driven Strategies for Translational Bioelectrical Interfaces
Featuring Bozhi Tian, professor at the University of Chicago department of Chemistry
Entanglement in Tensor Networks- Dr. Andrej Gendiar, School of Physics CM/AMO/Quantum Seminar
Tensor Networks are special classes of variational quantum states typically applied to study strongly correlated many-body systems.
Fossil Friday
Come join the Spatial Ecology and Paleontology Lab for Fossil Fridays! Become a fossil hunter and help discover how vertebrate communities have changed through time.
Observatory Public Night
On the grounds between the Howey and Mason Buildings, several telescopes are typically set up for viewing, and visitors are invited to bring their own telescope, as well.
C-PIES Summer Cookout
Join fellow College of Sciences faculty, staff, students, and alumni for food, games, and fun.
Experts in the News
Postdoctoral 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 2024-09-05T00:00:00-04:00Georgia Tech researchers from the School of Physics including fifth-year PhD student Mengqi Huang and Assistant Professor Chunhui Rita Du are among the authors of a paper recently published in Nature Physics. Researchers from six universities and Oak Ridge National Laboratory showed that strong quantum fluctuations can stabilize an unconventional magnetic phase after destroying a more conventional one.
Nature Physics 2024-08-26T00:00:00-04:00
