Analogue spacetime based on 2-component Bose-Einstein condensates

TL;DR

This paper demonstrates how a 2-component Bose-Einstein condensate can model various pseudo-Finsler and pseudo-Riemannian geometries, providing insights into Lorentz violations, mass generation, and the naturalness problem relevant to high-energy physics and cosmology.

Contribution

It introduces a novel analogue spacetime model using 2-component Bose-Einstein condensates capable of simulating complex geometries and Lorentz violation phenomena.

Findings

Able to model bi-metric and single metric geometries

Shows relation between quasi-particle mass and Lorentz violations

Exhibits Lorentz violation effects at high energies

Abstract

Analogue spacetimes are powerful models for probing the fundamental physical aspects of geometry - while one is most typically interested in ultimately reproducing the pseudo-Riemannian geometries of interest in general relativity and cosmology, analogue models can also provide useful physical probes of more general geometries such as pseudo-Finsler spacetimes. In this chapter we shall see how a 2-component Bose-Einstein condensate can be used to model a specific class of pseudo-Finsler geometries, and after suitable tuning of parameters, both bi-metric pseudo-Riemannian geometries and standard single metric pseudo-Riemannian geometries, while independently allowing the quasi-particle excitations to exhibit a "mass". Furthermore, when extrapolated to extremely high energy the quasi-particles eventually leave the phononic regime and begin to act like free bosons. Thus this analogue spacetime exhibits an analogue of the "Lorentz violation" that is now commonly believed to occur at or near the Planck scale defined by the interplay between quantum physics and gravitational physics. In the 2-component Bose-Einstein analogue spacetime we will show that the mass generating mechanism for the quasi-particles is related to the size of the Lorentz violations. This relates the "mass hierarchy" to the so-called "naturalness problem". In short the analogue spacetime based on 2-component Bose-Einstein condensates exhibits a very rich mathematical and physical structure that can be used to investigate many issues of interest to the high-energy physics, cosmology, and general relativity communities.