Quantum walk and Anderson localization of rotational excitations in disordered ensembles of polar molecules

TL;DR

This study investigates how rotational excitations in disordered ultracold molecular lattices exhibit Anderson localization, highlighting the influence of long-range tunnelling and vacancy concentration on localization phenomena across different dimensions.

Contribution

It provides a detailed analysis of Anderson localization in disordered molecular ensembles, emphasizing the effects of long-range tunnelling and vacancy levels in 1D, 2D, and 3D systems with realistic parameters.

Findings

Localization occurs in 1D and 2D systems within 1 second.

3D lattices with high vacancy rates show no localization.

Long-range tunnelling influences localization width in 2D lattices.

Abstract

We consider the dynamics of rotational excitations placed on a single molecule in spatially disordered 1D, 2D and 3D ensembles of ultracold molecules trapped in optical lattices. The disorder arises from incomplete populations of optical lattices with molecules. This leads to a model corresponding to a quantum particle with long-range tunnelling amplitudes moving on a lattice with the same on-site energy but with forbidden access to random sites (vacancies). We examine the time and length scales of Anderson localization for this type of disorder with realistic experimental parameters in the Hamiltonian. We show that for an experimentally realized system of KRb molecules on an optical lattice this type of disorder leads to disorder-induced localization in 1D and 2D systems on a time scale $t \sim 1$ sec. For 3D lattices with $55$ sites in each dimension and vacancy concentration $ 90~\%$, the rotational excitations diffuse to the edges of the lattice and show no signature of Anderson localization. We examine the role of the long-range tunnelling amplitudes allowing for transfer of rotational excitations between distant lattice sites. Our results show that the long-range tunnelling has little impact on the dynamics in the diffusive regime but affects significantly the localization dynamics in lattices with large concentrations of vacancies, enhancing the width of the localized distributions in 2D lattices by more than a factor of 2. Our results raise a general question whether quantum particles with long-range tunnelling can undergo quantum localization in 3D lattices with substitutional disorder.