A new study led by the Department of Energy's Lawrence Berkeley National Laboratory (Berkeley Lab) has measured how long it takes for several kinds of exotic nuclei to decay. The paper, published in Physical Review Letters, marks the first experimental result from the Facility for Rare Isotope Beams (FRIB), a DOE Office of Science user facility operated by Michigan State University.

Scientists used the one-of-a-kind facility to better understand nuclei, the collection of protons and neutrons found at the heart of atoms. Understanding these basic building blocks allows scientists to refine their best models and has applications in medicine, national security, and industry.

"The breadth of the facility and the programs that are being pursued are really exciting to watch," said Heather Crawford, a physicist at Berkeley Lab and lead spokesperson for the first FRIB experiment. "Research is going to be coming out in different areas that will impact things we haven't even thought of yet. There's so much discovery potential."

The first experiment is just a small taste of what's to come at the facility, which will become 400 times more powerful over the coming years. "It's going to be really exciting - mind-blowing, honestly," Crawford said.

More than 50 participants from ten universities and national laboratories were involved in the first experiment. The study looked at isotopes of several elements. Isotopes are variations of a particular element; they have the same number of protons but can have different numbers of neutrons.

Researchers focused on unstable isotopes near the "drip-line," the spot where neutrons can no longer bind to a nucleus. Instead, any additional neutrons drip off, like water from a saturated kitchen sponge.

Researchers smashed a beam of stable calcium-48 nuclei traveling at about 60% of the speed of light into a beryllium target. The calcium fragmented, producing a slew of isotopes that were separated, individually identified, and delivered to a sensitive detector that measured how long they took to decay. The result? The first reported measurements of half-lives for five exotic, neutron-laden isotopes of phosphorus, silicon, aluminum, and magnesium.

Half-life measurements (perhaps best known from applications in carbon dating) are one of the first things researchers can observe about these short-lived particles. The fundamental information about nuclei at the limits of their existence provides a useful test for different models of the atomic world.

"This is a basic science question, but it links to the bigger picture for the field," Crawford said. "Our aim is to describe not only these nuclei, but all kinds of nuclei. These models help us fill in the gaps, which helps us more reliably predict things we haven't been able to measure yet."

More complete theories help advance research in areas such as astrophysics and nuclear physics - for example, understanding how elements form in exploding stars or how processes unfold in nuclear reactors.

Crawford and the team plan to repeat the half-life experiment again next year, taking advantage of additional beam intensity that will increase the number of isotopes produced, including rare isotopes near the neutron drip-line. In the meantime, other groups will take advantage of the facility's many beamlines and instruments.

"Bringing the facility online was a big effort by a lot of people, and something the community has been looking forward to for a long time," Crawford said. "I'm excited I am young enough to keep taking advantage of it for the next several decades."

Multiple institutions collaborated on the first experiment, with researchers from Argonne National Laboratory (ANL), Berkeley Lab, Brookhaven National Laboratory, Florida State University, FRIB, Lawrence Livermore National Laboratory, Louisiana State University, Los Alamos National Laboratory, Mississippi State University, Oak Ridge National Laboratory (ORNL), and the University of Tennessee Knoxville (UTK).

Scientists from ORNL, UTK, ANL and FRIB led the collaboration to provide the instruments used in the FRIB Decay Station initiator, the sensitive detector system that measured the isotopes.

Michigan State University (MSU) operates the Facility for Rare Isotope Beams (FRIB) as a user facility for the U.S. Department of Energy Office of Science (DOE-SC), supporting the mission of the DOE-SC Office of Nuclear Physics. Hosting what is designed to be the most powerful heavy-ion accelerator, FRIB enables scientists to make discoveries about the properties of rare isotopes in order to better understand the physics of nuclei, nuclear astrophysics, fundamental interactions, and applications for society, including in medicine, homeland security, and industry.

Research Report:Crossing N = 28 Toward the Neutron Drip Line: First Measurement of Half-Lives at FRIB

Related Links
Lawrence Berkeley National Laboratory
Understanding Time and Space

Tweet

Thanks for being there; We need your help. The SpaceDaily news network continues to grow but revenues have never been harder to maintain. With the rise of Ad Blockers, and Facebook - our traditional revenue sources via quality network advertising continues to decline. And unlike so many other news sites, we don't have a paywall - with those annoying usernames and passwords. Our news coverage takes time and effort to publish 365 days a year. If you find our news sites informative and useful then please consider becoming a regular supporter or for now make a one off contribution.
SpaceDaily Monthly Supporter $5+ Billed Monthly Option 1 : $5.00 USD - monthly Option 2 : $10.00 USD - monthly Option 3 : $15.00 USD - monthly Option 4 : $20.00 USD - monthly Option 5 : $25.00 USD - monthly Option 6 : $50.00 USD - monthly Option 7 : $100.00 USD - monthly paypal only		SpaceDaily Contributor $5 Billed Once credit card or paypal

Magnetic quantum fluid: extremely fluid in two ways
Heidelberg, Germany (SPX) Nov 09, 2022
Two superfluids can exist at the same time in ultracold atomic clouds. Until now, their coexistence could not be observed experimentally. Now, however, physicists from Heidelberg University have demonstrated such a magnetic quantum fluid - it is fluid in two ways - in an atomic gas. Researchers led by Prof. Dr Markus Oberthaler have succeeded in preparing this state in clouds of ultracold rubidium atoms and to characterise it in detail. The results of their research were published in the journal Nature ... read more