Exchange Interactions of a Wigner Crystal in a Magnetic Field and Berry Curvature: Multi-Particle Tunneling through Complex Trajectories

TL;DR

This paper investigates how magnetic fields and Berry curvature influence exchange interactions in a 2D Wigner crystal, revealing complex multi-particle tunneling processes and phase effects that modify exchange constants.

Contribution

It introduces a semi-classical approach to account for magnetic and Berry curvature effects on exchange interactions via complex trajectories and phases.

Findings

Exchange constants acquire Aharonov-Bohm phases due to magnetic fields.

Berry curvature induces Berry phases along imaginary momentum-space trajectories.

Both effects modify the magnitude and phase of exchange interactions.

Abstract

We study how an out-of-plane magnetic field $B({\bf r})$ and a Berry curvature $\Omega({\bf k})$ modify the exchange interactions in a two-dimensional Wigner crystal (WC) using a semi-classical large-$r_s$ expansion. When only a magnetic field is present, ring-exchange processes arise from multi-particle tunneling through {\it complex} trajectories which constitute {\it complex instanton} solutions of the coordinate-space path integral. To leading order in $B$, each exchange constant $J_a$ acquires an Aharonov-Bohm phase along the zero-field tunneling trajectory. When a Berry curvature is present, the multi-particle tunneling must be considered in a complexified phase space $({\bf r}, {\bf k})$. To leading order in $\Omega$, $J_a$ acquires a Berry phase along a {\it purely imaginary} momentum-space trajectory. When $B$ and $\Omega$ are both present, in addition to having both Aharonov-Bohm and Berry phases, the exchange magnitude $|J_a|$ is also modified due to an effective-mass renormalization. These effects could be relevant for the WC and proximate phases recently observed in rhombohedral multilayer graphene.