Nuclear Physics from Lattice QCD

Last updated on Aug 13, 2021

Artwork by Dr. Evan Berkowitz and Bart-W. van Lith.

Baryons, like the neutron and the proton, are composite particles made up of elementary quarks and gluons, interacting very strongly with each other. The strong interactions make the equations of the mathematical theory we use to describe quarks and gluons, namely Quantum Chromodynamics (QCD), impossible to solve analytically with pen and paper methods. Powerful numerical methods are required. We employ Lattice Quantum Field Theory methods, relying on Markov Chain Monte Carlo stochastic sampling techniques to evaluate a large-dimensional Feynman Path Integral.

With numerical computations we study how quark and gluons determine the fundamental properties of neutrons and protons, such as their weak interaction form factors and their strong interactions, which are important for nuclear fusion reactions fueling our Sun and nuclei formation in the early universe.

For more details see the webpage of the CalLat collaboration.

Publications

Nucleon Axial Form Factor from Domain Wall on HISQ

The Deep Underground Neutrino Experiment (DUNE) is an upcoming neutrino oscillation experiment that is poised to answer key questions …

Aaron S. Meyer, Evan Berkowitz, Chris Bouchard, Chia Cheng Chang, M. A. Clark, Ben Hörz, Dean Howarth, Christopher Körber, Henry Monge-Camacho, Amy Nicholson, Enrico Rinaldi, Pavlos Vranas, Andre Walker-Loud

Neutron-antineutron oscillations from lattice QCD

Fundamental symmetry tests of baryon number violation in low-energy experiments can probe beyond the standard model (BSM) explanations of the matter-antimatter asymmetry of the Universe. Neutron-antineutron oscillations are predicted to be a signature of many baryogenesis mechanisms involving low-scale baryon number violation. This publication presents first-principles calculations of neutron-antineutron matrix elements needed to accurately understand measurements of the neutron-antineutron oscillation rate.

Enrico Rinaldi, Sergey Syritsyn, Michael L. Wagman, Michael I. Buchoff, Chris Schroeder, Joseph Wasem

Neutron-antineutron oscillations from lattice QCD

A per-cent-level determination of the nucleon axial coupling from quantum chromodynamics

For the first time we directly calculate a fundamental property of the neutron from the equations of quantum chromodynamics without relying on experimental measurements. We reach a sub-percent precision, many years ahead of what was previously conceived, thanks to a new algorithmical improvement to reduce the stochastic noise in our calculation.

Chia Cheng Chang, Amy Nicholson, Enrico Rinaldi, Evan Berkowitz, Nicolas Garron, David Brantley, Henry Monge-Camacho, Christopher Monahan, Chris Bouchard, M. A. Clark, Balint Joo, Thorsten Kurth, Kostas Orginos, Pavlos Vranas, Andre Walker-Loud