An interpolatory ansatz captures the physics of one-dimensional confined Fermi systems

TL;DR

This paper introduces a simple interpolatory ansatz that accurately models one-dimensional confined Fermi systems across all interaction strengths, including non-integrable mixed-mass systems, by combining known solutions at interaction limits.

Contribution

The authors propose a linear combination approach that captures the physics of confined 1D Fermi systems for all interaction strengths, extending applicability beyond integrable models.

Findings

Accurately describes systems with up to six particles.

Works for mixed-mass, non-integrable systems.

Provides a simple alternative to complex numerical methods.

Abstract

Interacting one-dimensional quantum systems play a pivotal role in physics. Exact solutions can be obtained for the homogeneous case using the Bethe ansatz and bosonisation techniques. However, these approaches are not applicable when external confinement is present. Recent theoretical advances beyond the Bethe ansatz and bosonisation allow us to predict the behaviour of one-dimensional confined systems with strong short-range interactions, and new experiments with cold atomic Fermi gases have already confirmed these theories. Here we demonstrate that a simple linear combination of the strongly interacting solution with the well-known solution in the limit of vanishing interactions provides a simple and accurate description of the system for all values of the interaction strength. This indicates that one can indeed capture the physics of confined one-dimensional systems by knowledge of the limits using wave functions that are much easier to handle than the output of typical numerical approaches. We demonstrate our scheme for experimentally relevant systems with up to six particles. Moreover, we show that our method works also in the case of mixed systems of particles with different masses. This is an important feature because these systems are known to be non-integrable and thus not solvable by the Bethe ansatz technique.