The BCS-BEC crossover: From ultra-cold Fermi gases to nuclear systems

TL;DR

This paper reviews the BCS-BEC crossover phenomenon, highlighting its experimental realization in ultra-cold Fermi gases and exploring its implications for nuclear physics, especially in understanding nuclear matter and neutron stars.

Contribution

It provides a comparative analysis of the BCS-BEC crossover in ultra-cold gases and nuclear matter, emphasizing theoretical approaches and potential solutions to open problems in nuclear physics.

Findings

Experimental realization of BCS-BEC crossover in ultra-cold gases

Theoretical insights into pairing and superfluidity in nuclear matter

Connections between cold atom experiments and nuclear physics phenomena

Abstract

This report adresses topics and questions of common interest in the fields of ultra-cold gases and nuclear physics in the context of the BCS-BEC crossover. The BCS-BEC crossover has recently been realized experimentally, and essentially in all of its aspects, with ultra-cold Fermi gases. This realization, in turn, has raised the interest of the nuclear physics community in the crossover problem, since it represents an unprecedented tool to test fundamental and unanswered questions of nuclear many-body theory. Here, we focus on the several aspects of the BCS-BEC crossover, which are of broad joint interest to both ultra-cold Fermi gases and nuclear matter, and which will likely help to solve in the future some open problems in nuclear physics (concerning, for instance, neutron stars). Similarities and differences occurring in ultra-cold Fermi gases and nuclear matter will then be emphasized, not only about the relative phenomenologies but also about the theoretical approaches to be used in the two contexts. After an introduction to present the key concepts of the BCS-BEC crossover, this report discusses the mean-field treatment of the superfluid phase, both for homogeneous and inhomogeneous systems, as well as for symmetric (spin- or isospin-balanced) and asymmetric (spin- or isospin-imbalanced) matter. Pairing fluctuations in the normal phase are then considered, with their manifestations in thermodynamic and dynamic quantities. The last two Sections provide a more specialized discussion of the BCS-BEC crossover in ultra-cold Fermi gases and nuclear matter, respectively. The separate discussion in the two contexts aims at cross communicating to both communities topics and aspects which, albeit arising in one of the two fields, share a strong common interest.