Quantum Hall phases and plasma analogy in rotating trapped Bose gases

TL;DR

This paper explores the quantum Hall phases in rotating Bose gases, using plasma analogy and Coulomb gas models to improve energy estimates and analyze density distributions for various trapping potentials.

Contribution

It advances the understanding of bosonic quantum Hall states by analyzing trial state densities through plasma analogy, extending previous models to more general trapping potentials.

Findings

Density of trial states analyzed via plasma analogy.

Improved energy estimates for ground states.

Extended analysis to more general trapping potentials.

Abstract

A bosonic analogue of the fractional quantum Hall eff ect occurs in rapidly rotating trapped Bose gases: There is a transition from uncorrelated Hartree states to strongly correlated states such as the Laughlin wave function. This physics may be described by eff ective Hamiltonians with delta interactions acting on a bosonic N-body Bargmann space of analytic functions. In a previous paper [N. Rougerie, S. Serfaty, J. Yngvason, Phys. Rev. A 87, 023618 (2013)] we studied the case of a quadratic plus quartic trapping potential and derived conditions on the parameters of the model for its ground state to be asymptotically strongly correlated. This relied essentially on energy upper bounds using quantum Hall trial states, incorporating the correlations of the Bose-Laughlin state in addition to a multiply quantized vortex pinned at the origin. In this paper we investigate in more details the density of these trial states, thereby substantiating further the physical picture described in [N. Rougerie, S. Serfaty, J. Yngvason, Phys. Rev. A 87, 023618 (2013)], improving our energy estimates and allowing to consider more general trapping potentials. Our analysis is based on the interpretation of the densities of quantum Hall trial states as Gibbs measures of classical 2D Coulomb gases (plasma analogy). New estimates on the mean- field limit of such systems are presented.