Universal Origin for Environment-Assisted Quantum Transport in Exciton Transfer Networks

TL;DR

This paper reveals a universal explanation for environment-assisted quantum transport (ENAQT) in exciton transfer networks, showing it arises from the interplay of dephasing effects and exciton density gradients, with implications for natural and artificial systems.

Contribution

It provides a universal, physics-based explanation for ENAQT in quantum networks with dephasing, unifying previous disparate theories.

Findings

ENAQT results from competing processes: dephasing-induced uniformity and density gradients.

A geometric condition for ENAQT emergence in quantum networks.

The explanation applies to both natural and artificial exciton transfer systems.

Abstract

Environment-assisted quantum transport (ENAQT) is the possibility of an external environment to enhance transport efficiency of quantum particles. This idea has generated much excitement over recent years, especially due to the experimentally-motivated possibility of ENAQT in photo-synthetic exciton transfer complexes. Many theoretical calculations have shown ENAQT, but the explanations for its origin differ, and a universal explanation has been elusive. Here we demonstrate a universal origin for ENAQT in quantum networks with a dephasing environment, based on a relation between exciton current and occupation within a Markovian open quantum system approach. We show that ENAQT appears due to two competing processes, namely the tendency of dephasing to make the exciton population uniform, and the formation of an exciton density gradient, defined by the source and the sink. Furthermore, we find a geometric condition on the network for the appearance of ENAQT, relevant to natural and artificial systems.