Few-Body Route to One-Dimensional Quantum Liquids

TL;DR

This paper introduces a simple collisional method to determine low-energy properties of one-dimensional quantum liquids, accurately matching known results and predicting critical behavior near phase transitions.

Contribution

A novel collisional approach for extracting Luttinger liquid parameters from many-body systems, avoiding complex non-perturbative calculations.

Findings

Accurately reproduces known results for integrable models.

Matches Monte Carlo simulations for helium and hydrogen isotopes.

Predicts the critical point and divergence exponent for helium-4.

Abstract

Gapless many-body quantum systems in one spatial dimension are universally described by the Luttinger liquid effective theory at low energies. Essentially, only two parameters enter the effective low-energy description, namely the speed of sound and the Luttinger parameter. These are highly system dependent and their calculation requires accurate non-perturbative solutions of the many-body problem. Here, we present a simple method that only uses collisional information to extract the low-energy properties of these systems. Our results are in remarkable agreement with available results for integrable models and from large scale Monte Carlo simulations of one-dimensional helium and hydrogen isotopes. Moreover, we estimate theoretically the critical point for spinodal decomposition in one-dimensional helium-4, and show that the exponent governing the divergence of the Luttinger parameter near the critical point is exactly 1/2, in excellent agreement with Monte Carlo simulations.