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.
The World Health Organization has identified antimicrobial resistance as a worldwide concern because most clinical antibiotics are no longer effective against certain pathogenic bacteria. Antibiotics work by targeting specific parts of a bacteria cell, such as the cell wall or its DNA. Bacteria can become resistant to antibiotics in a number of ways, including by developing efflux pumps — proteins that are located on the surface of the bacteria cell. When an antibiotic enters the cell, the efflux pump pumps it out of the cell before it can reach its target so that the antibiotic is never able to kill the bacteria. However, in a new study published in Nature Communications, scientists say they've found a new class of molecules that inhibit the efflux pump and make the antibiotic effective again. The researchers include Katie M. Kuo, Ph.D. scholar in the School of Chemistry and Biochemistry, and James C. Gumbart, professor in the School of Chemistry and Biochemistry with an adjunct appointment in the School of Physics.
SciTechDaily 2023-10-06T00:00:00-04:00Some insects can flap their wings so rapidly that it’s impossible for instructions from their brains to entirely control the behaviour. Building tiny flapping robots has helped researchers shed light on how they evolved to do this. For some insects, including mosquitoes, their brain signals and flapping are out of sync. After the initial signal to contract, the insects’ muscles undergo additional contract-relax cycles before they even receive another impulse from the brain. This so-called “asynchronous” flight allows them to flap their wings at exceptionally high rates. Several researchers from Georgia Tech set out to study the evolutionary history of this form of flight. Those researchers include Simon Sponberg, Dunn Family Associate Professor in the School of Physics and the School of Biological Sciences; Brett Aiello, former postdoctoral scholar in Sponberg's Agile Systems Lab; Ethan Wold, Ph.D. scholar in the School of Biological Sciences and the Quantitative Biosciences Graduate Program; and Jeff Gau, Ph.D. scholar in the George W. Woodruff School of Mechanical Engineering and the Interdisciplinary Bioengineering Graduate Program. (This research was also covered at India Education Diary, ArsTechnica, UC San Diego, Earth.com and Phys.org.)
New Scientist 2023-10-04T00:00:00-04:00Laura Cadonati, Associate Dean for Research in the College of Sciences and a professor in the School of Physics, will serve as a General Councilor for the American Physical Society, following recent APS elections. Her term will begin January 1, 2024. Cadonati, who is also a member of Georgia Tech's Center for Relativistic Astrophysics, will join other elected members to advise the Society on all matters regarding science and membership, including science policy. "Throughout my research journey in nuclear physics, astrophysics, and gravity, along with my active participation in large scientific collaborations, I have developed an understanding of the interconnectedness and the different traditions in various branches of physics," Cadonati says. "These insights will enable me to represent the wide constituency of APS."
American Physical Society 2023-09-28T00:00:00-04:00Around the coasts of the continents, where slopes sink down into the sea, tiny cages of ice called clathrates trap methane gas, preventing it from escaping and bubbling up into the atmosphere. Until now, the biological process behind how methane gas remains stable under the sea has been almost completely unknown. In a breakthrough study, a cross-disciplinary team of Georgia Tech researchers discovered a previously unknown class of bacterial proteins that play a crucial role in the formation and stability of methane clathrates. College of Sciences team members include Jennifer Glass, associate professor in the School of Earth and Atmospheric Sciences; Raquel Lieberman, professor and Sepcic-Pfeil Chair in the School of Chemistry and Biochemistry; Dustin Huard, a researcher in Lieberman’s lab and first author of the study; Abigail Johnson, a former Ph.D. student in Glass’ lab and co-first author on the paper, and James (JC) Gumbart, professor in the School of Physics. (The study was also covered at India Education Diary, SciTechDaily, Space.com, and Astrobiology.)
ScienceDaily 2023-09-27T00:00:00-04:00Researchers are exploring how active matter can be harnessed for tasks like designing new materials with tailored properties, understanding the behavior of biological organisms, and even developing new approaches to robotics and autonomous systems. But that’s only possible if scientists learn how the microscopic units making up active matter interact, and whether they can affect these interactions and thereby the collective properties of active matter on the macroscopic scale. School of Physics Professor Roman Grigoriev and his research colleagues have found a potential first step by developing a new model of active matter that generated new insight into the physics of the problem. They detail their methods and results in a new study published in Science Advances, “Physically informed data-driven modeling of active nematics.” Lead author of the study is graduate researcher Matthew Golden. Co-authors are graduate researcher Jyothishraj Nambisan and Alberto Fernandez-Nieves, professor in the Department of Condensed Matter Physics at the University of Barcelona and a former associate professor of Physics at Georgia Tech. (This research was also covered in WorldTimeTodays andCityLife.)
Phys.org 2023-09-04T00:00:00-04:00There’s no artist more vibrant, spiritual, or creative than Mother Earth. Then, we have mortals like Georgia Tech School of Physics alumni Dylan Diamond, who execute Mother Earth’s designs into functional tools or, in this case, a timepiece: “Moss Clock.” The clock has its own gear train and servo, or motors. The bottom line: this technology is a clock composed of living moss. Diamond had the idea to make a “digitally inspired” clock where moving panels of different colored moss resemble a classic digital clock display. "My physics degree helped, but I firmly believe that in the age of information, with public access to so many free tutorials and teachers online, anyone can do something like this," Diamond said.
Atlanta Jewish Times 2023-08-30T00:00:00-04:00The science world is remembering W. Jason Morgan, who in 1967 developed the theory of plate tectonics — a framework that revolutionized the study of earthquakes, volcanoes and the slow, steady shift of the continents across the earth’s mantle. Morgan, who died July 31 at his home in Natick, Mass., attended Georgia Tech and received his B.S. from the School of Physics in 1955.
The New York Times 2023-08-11T00:00:00-04:00Researchers have developed a method to construct solid objects that roll down pre-determined paths, which they reckon could have applications in quantum mechanics and medicine. To get a ball of malleable clay to roll down a simple path, you can force it down a specific path once, squashing it as you go. Take it to the top again, restart it from the initial starting point on the ball's surface, and it will roll down the same path. The researchers took this principle to develop an algorithm that could produce a shape capable of following almost any pre-determined path, even making the weird-shaped solids out of 3D-printed plastic and solid ball-bearings (for weight) to prove the point. Elisabetta Matsumoto, assistant professor in the School of Physics, co-wrote an accompanying article to the study saying "future work developing for more precise mathematical understanding of the issue would help to connect this work to applications, as well as to open up more purely mathematical veins of research."
The Register 2023-08-09T00:00:00-04:00J. Robert Oppenheimer, now the protagonist of a much-anticipated film, is today most known for his scientific leadership of the U.S. Manhattan Project, the World War II–era crash program to build the first-ever atomic bombs. But just a few years earlier, Oppenheimer had found himself pondering very different “weapons” of mass destruction: black holes — although it would be decades before that name arose. “It was influential; it was visionary,” says Feryal Özel, professor and chair of the School of Physics, of Oppenheimer’s work on black holes and neutron stars, the superdense corpses of expired massive stars. “He has a lasting impact.” Özel is a founding member of the Event Horizon Telescope Collaboration, which released the first-ever image of a black hole in 2019 — 80 years after Oppenheimer co-authored a paper theorizing that such objects could exist.
Scientific American 2023-07-21T00:00:00-04:00The heart’s electrical system keeps all its muscle cells beating in sync. A hard whack to the chest at the wrong moment, however, can set up unruly waves of abnormal electrical excitation that are potentially deadly. The resulting kind of arrhythmia may be what caused the football player Damar Hamlin of the Buffalo Bills to collapse on the field after he took a powerful hit during a 2023 National Football League game. In this Quanta podcast, Flavio Fenton, a professor in the School of Physics who studies the electrical dynamics of the heart, tells host Steve Strogatz about a new method under development for treating arrhythmias by stimulating the heart with mild, precisely timed shocks — or possibly even with light.
Quanta Magazine 2023-07-12T00:00:00-04:00Human beings for millennia have gazed with awe at the vast torrent of stars — bright and dim — shining in Earth's night sky that comprise the Milky Way. Our home galaxy, however, is now being observed for the first time in a brand new way. Scientists said on Thursday they have produced an image of the Milky Way not based on electromagnetic radiation - light - but on ghostly subatomic particles called neutrinos. They detected high-energy neutrinos in pristine ice deep below Antarctica's surface, then traced their source back to locations in the Milky Way - the first time these particles have been observed arising from our galaxy. "This observation is ground-breaking. It established the galaxy as a neutrino source. Every future work will refer to this observation," said Ignacio Taboada, professor in the School of Physics and spokesperson for the IceCube research collaboration in Antarctica that produced the image. (The story was also covered in NPR, Popular Mechanics, Smithsonian Magazine, Yahoo! News UK, Yahoo! News Canada, The Jerusalem Post, KPBS, Interactions.org, APS (American Physical Society), Vice, El Pais, VOA Learning English, bdnews24, SciTechDaily, PetaPixel, and Sinc.)
Reuters 2023-06-29T00:00:00-04:00Georgia Tech researchers have been selected by NASA to lead a $7.5 million center that will study the lunar environment and the generation and properties of volatiles and dust. The Center for Lunar Environment and Volatile Exploration Research (CLEVER) will be led by Thomas Orlando, professor in the School of Chemistry and Biochemistry with an adjunct appointment in the School of Physics. CLEVER is the successor to Orlando’s pioneering REVEALS (Radiation Effects on Volatiles and Exploration of Asteroids and Lunar Surfaces) center, and both are part of NASA’s Solar System Exploration Research Virtual Institute (SSERVI) program.
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An observatory still under construction at the bottom of the Mediterranean Sea has spotted what could be the most energetic neutrino ever detected. Such ultra-high-energy neutrinos — tiny subatomic particles that travel at nearly the speed of light — have been known to exist for only a decade or so, and are thought to be messengers from some of the Universe’s most cataclysmic events, such as growth spurts of supermassive black holes in distant galaxies. “It would be really interesting to see where in the sky the neutrino originated,” says Nepomuk Otte, an associate professor in the School of Physics. Otte is leading a proposed project — with a prototype now being tested in Utah — that would search for Earth-skimming neutrinos by monitoring the atmosphere just above the horizon for flashes of light.
Nature 2024-06-21T00:00:00-04:00Knitting, the age-old craft of looping and stitching natural fibers into fabrics, is gaining renewed attention for its potential in advanced manufacturing. Beyond creating garments, knitted textiles hold promise for designing wearable electronics and soft robotics – structures that need to move and bend flexibly. A team of physicists from the Georgia Institute of Technology has taken the technical know-how of knitting and added a mathematical foundation to it. Led by Elisabetta Matsumoto, associate professor in the School of Physics, and Krishma Singal, a graduate researcher in Matsumoto’s lab, the team used experiments and simulations to quantify and predict how knitted fabric responses can be programmed.
Earth.com 2024-06-20T00:00:00-04:00Robotics engineers have worked for decades, using substantial funding, to create robots that can walk or run with the ease of animals. Despite these efforts, today’s robots still cannot match the natural abilities of many animals in terms of endurance, agility, and robustness. Seeking to understand and quantify this disparity, an interdisciplinary team of scientists and engineers from top research institutions, including Dunn Family Associate Professor at the School of Physics and the School of Biological Sciences Simon Sponberg, conducted a comprehensive study to compare various aspects of robotic systems designed for running with their biological counterparts. (This also appeared at The Jerusalem Post, TechXplore, and SciTechDaily.)
Earth.com 2024-04-26T00:00:00-04:00A group of researchers at the Georgia Institute of Technology have created the world’s first functional semiconductor made from graphene, a development that could lead to advanced electronic devices and quantum computing applications. Seen as the building block of electronic devices, semiconductors are essential for communications, computing, healthcare, military systems, transportation and countless other applications. Semiconductors are typically made from silicon, but this material is reaching its limit in the face of increasingly faster computing and smaller electronic devices, according to the Georgia Tech research team who published their findings in Nature earlier this year. In a drive to find a viable alternative to silicon, Walter de Heer, Regents' Professor in the School of Physics, led a team of researchers based in Atlanta, Georgia and Tianjin, China to produce a graphene semiconductor that is compatible with microelectronics processing methods.
Gas World 2024-04-26T00:00:00-04:00In an opinion published in the May 2024 edition of APSNews, School of Physics Professor Andrew Zangwill reflects on the debate on the boundaries of physics and its impact on the discipline. Zangwill states “for more than a century, physicists have been drawing and redrawing the borders around the field, embracing and rejecting subfields along the way.”
American Physical Society News 2024-04-12T00:00:00-04:00The stars aligned to give a Georgia Tech undergraduate student and an alum the moment of a lifetime during the recent solar eclipse. Corinne Hill is currently majoring in physics with a concentration in astrophysics. Nathaniel Greve graduated in 2023 with a degree in computer science. The couple met in 2021 when they both played alto saxes in the Georgia Tech marching band. After being unable to experience totality in 2017, Greve said the pair made plans to go to Wapakoneta, Ohio, for 2024′s eclipse. Hill’s friends in the Astronomy Club went to the Ozarks to experience the eclipse, but Hill agreed to go to Ohio instead.
Atlanta News First 2024-04-11T00:00:00-04:00
