Facility for Rare Isotope Beams

FRIB is featured in a list of Science's areas to watch in 2022. The fleeting atomic nuclei normally forged only in stellar explosions will find a home on Earth after the $730 million FRIB fires up at Michigan State University. The world’s most powerful ion source, the linear accelerator can fire any nucleus—from hydrogen’s single proton to uranium atoms’ massive core—into targets to produce new, unstable nuclei.

FRIB was featured in a list of themes set to shape research in 2022. The multi-stage accelerator aims to synthesize thousands of new isotopes of known elements, and it will investigate nuclear structure and the physics of neutron stars and supernova explosions.

The U.S. Department of Energy Office of Science (DOE-SC) posted a highlight about the FRIB-affiliated Lee Research Group’s research paper titled “Rodeo Algorithm for Quantum Computing” published in Physical Review Letters. DOE-SC posts about 200 published research findings annually, selected by their respective program areas in DOE-SC as publication highlights of special note.

A team of researchers, including scientists from the National Superconducting Cyclotron Laboratory and the Facility for Rare Isotope Beams at Michigan State University, have solved the case of zirconium-80’s missing mass.

One of the most spectacular quantum effects in atomic nuclei is the emergence of a shell structure. Important questions such as the origin of an additional binding energy in nuclei, where neutrons and protons occupy the same shell orbitals, remain open. Now, as they describe in Nature Physics, FRIB's Alec Hamaker and colleagues have provided answers to this question by performing accurate mass measurements of zirconium isotopes.

Achim Schwenk (Institute of Nuclear Physics at the Darmstadt University of Technology), a member of the FRIB Users Organization, has been named on the annual Highly Cited Researchers 2021 list from Clarivate. Clarivate is a scientific publication analytics firm. The list identifies researchers who demonstrated significant influence in their chosen field or fields through the publication of multiple highly cited papers during the last decade. Their names are drawn from the publications that rank in the top 1 percent by citations for field and publication year in the “Web of Science” citation index.

Researchers are queuing up to use a particle accelerator at Michigan State University to study some of the rarest atomic nuclei. When it opens in early 2022, the Facility for Rare Isotope Beams will strip electrons off of atoms to make ions, rev them up to high speeds and then send them crashing into a target to make the special nuclei that scientists want to study.

About 20 years ago, a Michigan State University physicist had an idea to reveal insights about a fundamental but enigmatic force at work in some of the most extreme environments in the universe. These environments include an atom's nucleus and celestial bodies known as neutron stars, both of which are among the densest objects known to humanity.

The American Physical Society (APS) announced that it has selected FRIB’s Paul Guèye as the 2022 Edward A. Bouchet Award winner. APS recognized Guèye for his “many seminal experimental contributions to understanding the structure of nuclear particles and decades of service to physics outreach, diversity and inclusion.”

A drive to learn has propelled 16-year-old Maya Wallach to finish high school early and enroll at Michigan State University, where she is a sophomore studying experimental physics, and an intern at the Facility for Rare Isotope Beams.

Scientists at MSU’s FRIB have built and tested a device that will allow pivotal insights into heavy elements, or elements with very large numbers of protons and neutrons. Ben Kay, physicist at Argonne National Laboratory, led this effort.

The $730 million FRIB at MSU is scheduled to come online in early 2022 – a game-changer in every sense for the U.S. and international nuclear-physics communities. With peer review and approval of the first round of experimental proposals now complete, an initial cohort of scientists from 25 countries is making final preparations to exploit FRIB’s unique capabilities.

New research by the University of Surrey's Nuclear Physics Group has shown that it's possible to mimic excited quantum states with exotic nuclei, opening up a host of opportunities for next generation radioactive beam facilities, such as the Facility for Rare Isotope Beams.

Scientists explore the origin of aluminum-26 in stars with a nuclear reaction that exploits the fact that neutrons and protons are stunningly similar. Scientists from the University of Surrey and the FRIB Laboratory at MSU teamed up to explore the origin of aluminum-26.

Filomena Nunes, managing director of the FRIB Theory Alliance, discusses how the limits of nuclear stability provide deep insights into the fundamental force responsible for the presence of matter. Exotic nuclei are created, if only for an instant. A major ambition of our generation is to understand where and how heavy matter forms. Exotic neutron-rich nuclei are an essential piece of that puzzle.

MSU's $730 million Facility for Rare Isotope Beams is about 95-percent complete, said FRIB Laboratory Director Thomas Glasmacher. And scientists are already asking to use the FRIB’s 400-kilowatt superconducting linear accelerator. A subscription to the Lansing State Journal is required to view this article.

The upcoming Facility for Rare Isotope Beams in Michigan is a cutting-edge accelerator that promises great things for nuclear physicists, especially those with applications in mind.

Michigan State University received a $13 million federal grant to harvest isotopes at Facility for Rare Isotope Beams.

A $13 million project is aiming to harvest isotopes at Michigan State's Facility for Rare Isotope Beams.

Creating a new cutting-edge accelerator isn’t cheap or easy. But the upcoming Facility for Rare Isotope Beams in Michigan promises great things for nuclear physicists, especially those with applications in mind.

Scientists have identified three distinct shapes in stable nickel-64, a stable isotope of nickel. This discovery increases the predictive power of such nuclear structure calculations for nuclei that can only be reached at next-generation rare-isotope facilities such as the Facility for Rare Isotope Beams.