Physicists use numerical ‘tweezers’ to study nuclear interactions

“Ultimately we want to understand how nuclear forces determine nuclear structure by studying how nuclei attract or repel one another,” says Dean Lee, professor of physics at NC State and corresponding author of a paper describing the work. “So we needed a way to hold particles in place and move them around relative to one another in order to measure attraction or repulsion.”

Lee, along with Ruhr-Universität Bochum colleagues Evgeny Epelbaum and Hermann Krebs and graduate student Alexander Rokash, utilized a numerical lattice with attractive potentials in order to isolate the particles they wanted to study. The attractive potentials created a way for a particle to get “stuck” in one place — like a hole in the ground that a marble could roll into. These were the numerical tweezers.

The team began simulations with two single particles held in different positions, then with particle pairs. They looked at two types of interactions between the groups of particles: local interactions, where the particles’ positions relative to one another don’t change; and non-local interactions, where the positions do change.

“We found that the local interactions had a much bigger effect on determining whether nuclei would stick together, or become bound,” Lee says. “Specifically, the strength and range of the local interactions determined whether or not the nuclei would bind to each other. In non-local interactions, on the other hand, the nuclei sometimes repelled each other.

“We’re interested in finding out why nuclei bind together to form new elements,” Lee continues. “Numerical tweezers allow us to do simple simulations using just a few particles, giving us insight into the most basic particle interactions and the ways in which nuclear interactions inform nuclear structure.”

Story Source:

Materials provided by North Carolina State University. Note: Content may be edited for style and length.