Wavepacket dynamics on Chern band lattices in a trap

TL;DR

This paper investigates the dynamics of Gaussian wavepackets in Chern band lattices under a harmonic trap, highlighting the importance of wavepacket extent in momentum space for accurate semiclassical descriptions of their transverse motion.

Contribution

It demonstrates how finite wavepacket size and momentum support influence the accuracy of semiclassical models in topological lattice systems.

Findings

Wavepacket extent in momentum space affects dynamics accuracy.

Semiclassical models work well for large real-space wavepackets.

Dynamics depend on interplay of band dispersion and Berry curvature.

Abstract

The experimental realization of lattices with Chern bands in ultracold-atom and photonic systems has motivated the study of time-dependent phenomena, such as spatial propagation, in lattices with nontrivial topology. We study the dynamics of gaussian wavepackets on the Haldane honeycomb Chern-band lattice model, in the presence of a harmonic trap. We focus on the transverse response to a force, which is due partly to the Berry curvature and partly to the transverse component of the energy band curvature. We evaluate the accuracy of a semiclassical description, which treats the wavepacket as a point particle in both real and momentum space, in reproducing the motion of a realistic wavepacket with finite extent. We find that, in order to accurately capture the wavepacket dynamics, the extent of the wavepacket in momentum space needs to be taken into account. The dynamics is sensitive to the interplay of band dispersion and Berry curvature over the finite region of momentum (reciprocal) space where the wavepacket has support. Moreover, if the wavepacket is prepared with a finite initial momentum, the semiclassical analysis reproduces its motion as long as it has a large overlap with the eigenstates of a single band. The semiclassical description generally improves with increasing real-space size of the wavepacket, as long as the external conditions (e.g., external force) remain uniform throughout the spatial extent of the wavepacket.