Universality in QCD and Halo Nuclei

TL;DR

This paper reviews how Effective Field Theory reveals universal properties in quantum systems with large scattering lengths, including Efimov states and potential infrared limit cycles in QCD, with applications to cold atoms and halo nuclei.

Contribution

It extends EFT methods to explore universality in QCD and halo nuclei, highlighting the possibility of an infrared limit cycle and broadening the understanding of universal phenomena.

Findings

Identification of Efimov states in systems with large scattering length

Discussion of potential infrared limit cycle in QCD

Application of EFT to halo nuclei

Abstract

Effective Field Theory (EFT) provides a powerful framework to exploit a separation of scales in order to perform systematically improvable, model-independent calculations. We apply this method to strongly interacting quantum systems with short-range interactions and large scattering length. Such systems display remarkable universal properties which include a geometric spectrum of shallow three-body states called "Efimov states" and log-periodic dependence of scattering observables on the scattering length. We review the EFT for large scattering length and some of its applications in the physics of cold atoms and nuclear physics. In particular, we discuss the possibility of an infrared limit cycle in QCD and the extension of the EFT to halo nuclei.