Periodic Reporting for period 4 - PrecisionNuclei (Strong interactions for precision nuclear physics)
Periodo di rendicontazione: 2022-08-01 al 2023-01-31
In this project I will develop a novel methodology to use experimental information from heavy atomic nuclei in the construction of nuclear interactions from chiral effective field theory. I expect this approach to enable me and my team to make precise ab initio predictions of various nuclear observables in a wide mass-range from hydrogen to lead as well as infinite nuclear matter. I will apply Bayesian regression and methods from machine learning to quantify the statistical and systematic uncertainties of the theoretical predictions. The novelty and challenge in this project lies in synthesising (i) the design of nuclear interactions, (ii) ab initio calculations of nuclei, and (iii) statistical inference in the confrontation between theory and experimental data. This alignment of methods, harboured within the same project, will create a clear scientific advantage and allow me to tackle the following big research question: How well can atomic nuclei and nuclear matter be described in chiral effective field theories of quantum chromo dynamics?
The most important results include the development of eigenvector continuation for emulation and a novel technology called Subspace-Projected Coupled Cluster (SPCC). This is a game changer for the theoretical analyses of nuclei. In particular for performing Bayesian inference studies of nuclear properties to reveal patterns of the underlying nuclear interaction and to correlate experimental information across the nuclear chart. This project made key contributions to a breakthrough calculation of the neutron skin thickness in 208-Lead and aa novel statistical statistical analysis linking this result to details of chiral nuclear forces and the properties of infinite nuclear matter. These results were disseminated at international conferences and in high-impact scientific journals (Physical Review Letters and Nature Physics).