Influence of the coupled-dipoles on photosynthetic performance in a photosynthetic quantum heat engine

TL;DR

This paper investigates how coupled-dipoles influence photosynthetic efficiency in a quantum heat engine model, revealing that they can enhance performance by modulating quantum interference effects, with implications for biological and artificial energy systems.

Contribution

It introduces a novel model showing the role of coupled-dipoles in improving photosynthetic performance through quantum heat engine analysis.

Findings

Coupled-dipoles can significantly enhance photosynthetic performance.

Quantum interference is deactivated by coupled-dipoles, yet performance is still promoted.

The study suggests potential strategies for artificial photosynthesis based on these mechanisms.

Abstract

Recent evidence suggests that the multi charge-separation pathways can contribute to the photosynthetic performance. In this work, the influence of coupled-dipoles on the photosynthetic performance was investigated in a two-charge separation pathways quantum heat engine (QHE) model. And the population dynamics of the two coupled sites, j-V characteristics and power involving this photosynthetic QHE model were evaluated for the photosynthetic performance. The results illustrate that the photosynthetic performance can be greatly enhanced but quantum interference was deactivated by the coupled-dipoles between the two-charge separation pathways. However, the photosynthetic performance can also be promoted by the deactivated quantum interference owing to the coupled-dipoles. It is a novel role of the coupled-dipoles in the energy transport process of biological photosynthetic and some artificial strategies may be motivated by this photosynthetic QHE model in the future.