Dephasing enhanced transport of spin excitations in a two dimensional lossy lattice

TL;DR

This paper investigates how dephasing noise can enhance spin excitation transport efficiency in a two-dimensional lattice, revealing conditions under which environment-assisted quantum transport occurs.

Contribution

It provides numerical and analytical analysis of dephasing-enhanced transport in a 2D lattice, deriving approximate formulas and identifying regimes for optimal efficiency.

Findings

Dephasing noise can significantly improve excitation transfer efficiency.

Analytic expressions accurately describe ENAQT in different noise regimes.

Conditions for the occurrence of environment-assisted quantum transport are established.

Abstract

Noise is commonly regarded as an adverse effect disrupting communication and coherent transport processes or limiting their efficiency. However, as has been shown for example for small light-harvesting protein complexes decoherence processes can play a significant role in facilitating transport processes, a phenomenon termed environment-assisted quantum transport (ENAQT). We here study numerically and analytically how dephasing noise improves the efficiency of spin excitation transport in a two dimensional lattice with small homogeneous losses. In particular we investigate the efficiency and time of excitation transfer from a random initial site to a specific target site and show that for system sizes below a characteristic scale it can be substantially enhanced by adding small dephasing noise. We derive approximate analytic expressions for the efficiency which become rather accurate in the two limits of small (coherent regime) and large noise (Zeno regime) and give a very good overall estimate. These analytic expressions provide a quantitative description of ENAQT in spatially extended systems and allow to derive conditions for its existence.