New 2024 American Physical Society Fellow Jozef Dudek is pursuing theoretical descriptions of exotic hadrons, a yet-untallied group of short-lived subatomic cousins of the proton and neutron, those more familiar atomic building blocks.
Nuclear physics theorists have demonstrated that complex calculations run on supercomputers can accurately predict the distribution of electric charges in mesons, particles made of a quark and an antiquark. The calculations also help validate a method that will be used to make predictions for and analyze data from high-energy experiments at the future Electron-Ion Collider (EIC) at Brookhaven National Laboratory.
Scientists have demonstrated a new way to use high-energy particle smashups at the Relativistic Heavy Ion Collider (RHIC) to reveal subtle details about the shapes of atomic nuclei. The method is complementary to lower energy techniques for determining nuclear structure. It will add depth to scientists’ understanding of the nuclei that make up the bulk of visible matter.
The new Belle II experiment recently made a world-leading measurement of the lifetime of a particular charmed baryon, a particle that is produced and decays very quickly under very high energy levels similar to the universe shortly after the Big Bang. This demonstrates the experiment’s ability to make the extremely precise measurements of the sort needed to discover physics beyond the Standard Model of Particle Physics.
Researchers from the University of Washington, Seattle, or UW, and Los Alamos National Laboratory used the Summit supercomputer at the Department of Energy’s Oak Ridge National Laboratory to answer one of fission’s biggest questions: What exactly happens during the nucleus’s “neck rupture” as it splits in two?
Jefferson Lab’s Experimental Physics Software and Computing Infrastructure (EPSCI) group develops centralized computing software that can be shared by any of the lab’s experimental halls and used for future projects.
This year, the U.S. Department of Energy's Thomas Jefferson National Accelerator Facility celebrates the 40th anniversary of its founding to probe the secrets of the subatomic universe. And for 39 of those years, esteemed physicist Volker D. Burkert has been an important part of its mission. Now, Burkert is being honored for his contributions to advancements in experimental physics with the prestigious Tom W. Bonner Prize in Nuclear Physics. The citation reads: “For exemplary leadership in the development of high-performance instrumentation for large acceptance spectrometers that have enabled breakthroughs in fundamental nuclear physics through electroproduction measurements of exclusive processes."
One of the methods scientists use to study quantum many-body systems is the ab initio approach, but some ab initio methods run into severe computational problems when using realistic interactions. This study introduces wavefunction matching and uses it to perform lattice simulations with realistic interactions. This allows scientists to make calculations that were once impossible.
Scientists at the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory have designed and tested the world’s highest voltage polarized electron gun, a key piece of technology needed for building the world’s first fully polarized Electron-Ion Collider (EIC).
Researchers at the Facility for Rare Isotope Beams reached a new milestone in isotope studies, accelerating a high-power beam of uranium ions to a record 10.4 kilowatts of continuous beam power to a target. The beam enabled scientists to produce and identify three new isotopes, gallium-88, arsenic-93, and selenium-96.
As the Department of Energy (DOE) continues to accelerate a clean-energy future that includes fusion technology, a total of $49 million in funding for 19 projects was announced today in the Foundational Fusion Materials, Nuclear Science, and Technology programs.
The Scientific Data and Computing Center (SDCC) at the U.S. Department of Energy's (DOE) Brookhaven National Laboratory now stores more than 300 petabytes of data. That's far more data than would be needed to store everything written by humankind since the dawn of history — or, if you prefer your media in video format, all the movies ever created.
New method for cathode preparation prevents the particle cracking that caused performance decline with cycling of sodium-ion batteries, which offer a cheaper, more abundant alternative to lithium-ion batteries.
A new stellar process, the intermediate “i" process, has been proposed to explain new astronomical observations on nucleosynthesis. Scientists recently reported on the measurement of a nuclear reaction that affects the production of lanthanum in the i process. The measurement will help to improve scientific understanding of nucleosynthesis.
A new toolkit helps researchers build optimal superconducting radiofrequency (SRF) cavities that form the backbone of advanced particle accelerators. The cavities’ cleanliness, shape, and roughness of their inner surfaces contribute to their efficiency. In tests of the toolkit, scientists found that smoother cavities function more efficiently.
Deep inside what we perceive as solid matter, the landscape is anything but stationary. The interior of the building blocks of the atom’s nucleus — particles called hadrons that most of us would recognize as protons and neutrons — are made up of a seething mixture of interacting quarks and gluons, known collectively as partons. The HadStruc collaboration has now come together to map out these partons and disentangle how they interact to form hadrons. Their latest findings were recently published in the Journal of High Energy Physics.
As winners of the 2024 U.S. Department of Energy’s Early Career Research Program, four scientists from Argonne National Laboratory are each receiving an award of $550,000 a year for five years to help them answer complex questions.
Scientists uncover new experimental data that will help them better understand how heavy elements are created in stars and the processes that shape the chemical makeup of the universe.
The U.S. Department of Energy (DOE) today announced the selection of 91 early career scientists from across the country who will receive a combined $138 million in funding for research covering a wide range of topics including artificial intelligence, fusion energy, and quantum.
Spin is an intrinsic property of the electron. When electrons spin in the same direction at a given time, the quantity is called polarization. Understanding polarization helps examine the structure of nuclei of heavy elements. Now, nuclear physicists have measured the polarization of an electron beam more precisely than ever before.
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