http://arxiv.org/abs/2112.01125
Heavy atomic nuclei have an excess of neutrons over protons. This leads to the formation of a neutron skin whose thickness, $R_\mathrm{skin}$, is sensitive to details of the nuclear force — linking atomic nuclei to properties of neutron stars, thereby relating objects that differ in size by 18 orders of magnitude [1, 2]. ${}^{208}$Pb is of particular interest here because it exhibits a simple structure and is accessible to experiment. However, computing such a heavy nucleus has been out of reach for ab initio theory. By combining advances in quantum many-body methods, statistical tools, and emulator technology, we make quantitative predictions for the properties of ${}^{208}$Pb starting from nuclear forces that are consistent with symmetries of low-energy quantum chromodynamics. We explore $10^9$ different nuclear-force parameterisations via history matching, confront them with data in select light nuclei, and arrive at an importance-weighted ensemble of interactions. We accurately reproduce bulk properties of ${}^{208}$Pb and find $R_\mathrm{skin}({}^{208}\mathrm{Pb}) = 0.14-0.20$ fm which is smaller than a recent extraction from parity-violating electron scattering [3] but in agreement with other experimental probes. The allowable range of $R_\mathrm{skin}({}^{208}\mathrm{Pb})$ is significantly constrained by nucleon-nucleon scattering data, ruling out very thick skins. This work demonstrates that nuclear forces constrained to light systems extrapolate reliably to even the heaviest nuclei, and that we can make quantitative predictions across the nuclear landscape.
B. Hu, W. Jiang, T. Miyagi, et. al.
Fri, 3 Dec 21
33/81
Comments: N/A