Environmental engineering for quantum energy transport

TL;DR

This paper investigates how quantum environmental noise with specific spatio-temporal correlations can enhance energy transport efficiency in nanoscale systems, offering new insights and control strategies for quantum networks and biological complexes.

Contribution

It introduces a model analyzing quantum transport with colored and nonlocal noise, revealing how anti-correlations improve energy transfer efficiency.

Findings

Anti-correlated noise accelerates energy transfer rates.

Negative spatial correlations optimize transfer efficiency.

Spatio-temporal correlated noise benefits large-scale quantum networks.

Abstract

Transport phenomena are ubiquitous throughout the science, engineering and technology disciplines as it concerns energy, mass, charge and information exchange between systems. In particular, energy transport in the nanoscale regime has attracted significant attention within the physical science community due to its potential to explain complex phenomena like the electronic energy transfer in molecular crystals or the Fenna-Matthews-Olson / light harvesting complexes in photosynthetic bacteria with long time coherences. Energy transport in these systems is highly affected by environmental noise but surprisingly not always in a detrimental way. It was recently found that situations exist where noise actually enhances the transport phenomena. Such noise can take many forms, but can be characterised in three basic behaviours: quantum, coloured or nonlocal. All have been shown potential to offer an energy transport enhancement. The focus of this work is on quantum transport caused by stochastic environment with spatio-temporal correlation. We consider a multi-site nearest neighbour interaction model with pure dephasing environmental noise with coloured and nonlocal character and show how an accelerated rate for the energy transfer results especially under anti-correlation. Negative spatial correlations provide another control parameter to help one establish the most efficient transfer of energy and may provide new insights into the working of exciton transport in photosynthetic complexes. Further the usage of spatio-temporal correlated noise may be a beneficial resource for efficient transport in large scale quantum networks.