KAUST alumnus Dr. Muhammed Sameed works at CERN on the ALPHA project, studying antimatter. The project aims to understand why there is so little antimatter in the universe, given that physics equations predict equal amounts of matter and antimatter. Sameed's work involves creating, trapping, and studying antimatter particles in a controlled lab environment. Why it matters: This research advances our understanding of fundamental physics and the composition of the universe, with a KAUST alumnus playing a key role.
KAUST alumnus Muhammed Sameed, who completed his master's degree in material science and engineering in 2012, works at CERN on the ALPHA experiment, which uses lasers to measure the properties of anti-hydrogen. Researchers at CERN are investigating the fundamental structure of the universe, including the absence of anti-matter. Current research indicates that every process that creates matter also creates anti-matter in the same amount, which does not align with the observable universe. Why it matters: This highlights KAUST's role in training scientists who contribute to cutting-edge research in fundamental physics, even at international facilities like CERN.
Muhammed Sameed, a 2012 KAUST alumnus, co-authored a paper published in Nature about antimatter. Sameed currently works at CERN in Switzerland. The research was featured on the KAUST website. Why it matters: The publication highlights KAUST's role in fostering scientific talent who contribute to high-impact research globally, even if the specific research is not focused on the GCC region.
KAUST alumnus Muhammed Sameed, now a research scientist at CERN, co-authored a paper published in Nature on antimatter spectroscopy. Sameed contributed to CERN's ALPHA experiment, creating and studying antimatter particles. He credits KAUST for playing a pivotal role in his academic development and enabling a cross-disciplinary curriculum. Why it matters: The publication highlights KAUST's role in fostering talent that contributes to high-impact scientific research, enhancing the university's reputation and demonstrating its global impact.
Muhammed Sameed, a KAUST alumnus with a master's degree in material science and engineering, is working as a research scientist at CERN. He specializes in creating and studying antimatter particles as part of CERN's ALPHA experiment, with publications in Nature. Sameed advises students to be fearless and create new paths to maximize opportunities. Why it matters: This highlights KAUST's role in training scientists who contribute to cutting-edge international research, potentially inspiring further collaboration between KAUST and CERN.
A DeepMind researcher presented work on incorporating symmetries into machine learning models, with applications to lattice-QCD and molecular dynamics. The work includes permutation and translation-invariant normalizing flows for free-energy estimation in molecular dynamics. They also presented U(N) and SU(N) Gauge-equivariant normalizing flows for pure Gauge simulations and its extensions to incorporate fermions in lattice-QCD. Why it matters: Applying symmetry principles to generative models could improve AI's ability to model complex physical systems relevant to materials science and other fields in the region.
Communications Physics journal has a focus collection on space quantum communications. The collection covers supporting technologies, new quantum protocols, inter-satellite QKD, constellations of satellites, and quantum inspired technologies and protocols for space based communication. Contributions are welcome from October 20, 2020 to April 30, 2021, and accepted papers are published on a rolling basis. Why it matters: Space-based quantum communication is a critical area for developing secure, global quantum networks, and this collection could highlight relevant research for the GCC region as it invests in advanced technologies.
Researchers from LENS, CNR-INO, the University of Florence, UNAM, RPTU University Kaiserslautern-Landau, and TII Abu Dhabi have observed Shapiro steps in ultracold atoms for the first time. This allows for real-time observation of quantum mechanics and could lead to advanced quantum sensors and simulation. The experiments involved creating vortex-antivortex pairs, resulting in step-like signals, and the findings were published in Science. Why it matters: This breakthrough provides a new method to observe and control quantum coherence, potentially enabling advancements in quantum technologies and simulations within the region.