Trends and Progress in Nuclear and Hadron Physics: a straight or winding road

TL;DR

This paper reviews recent advances in theoretical calculations of hadron and nuclear properties, highlighting new methods, cross-disciplinary collaborations, and the growing importance of theory in experimental progress.

Contribution

It discusses the integration of non-perturbative renormalization, many-body methods, and computational algorithms across nuclear and hadronic physics, emphasizing their combined progress.

Findings

Theoretical predictions now rival experimental measurements.

Cross-fertilization enhances progress in both fields.

Hamiltonian Basis Light-Front Quantization yields recent results.

Abstract

Quantitative calculations of the properties of hadrons and nuclei, with assessed uncertainties, have emerged as competitive with experimental measurements in a number of major cases. We may well be entering an era where theoretical predictions are critical for experimental progress. Cross-fertilization between the fields of relativistic hadronic structure and non-relativistic nuclear structure is readily apparent. Non-perturbative renormalization methods such as Similarity Renormalization Group and Okubo-Lee-Suzuki schemes as well as many-body methods such as Coupled Cluster, Configuration Interaction and Lattice Simulation methods are now employed and advancing in both major areas of physics. New algorithms to apply these approaches on supercomputers are shared among these areas of physics. The roads to success have intertwined with each community taking the lead at various times in the recent past. I briefly sketch these fascinating paths and comment on some symbiotic relationships. I also overview some recent results from the Hamiltonian Basis Light-Front Quantization approach.