Geometry, supertransfer, and optimality in the light harvesting of purple bacteria

TL;DR

This paper investigates how the rotational symmetry of purple bacteria's light-harvesting complexes enhances energy transfer, demonstrating that natural symmetry significantly outperforms randomized configurations through supertransfer effects.

Contribution

It provides a detailed analysis of the role of symmetry in energy transfer efficiency, highlighting the importance of natural geometry in photosynthetic complexes.

Findings

Symmetry increases energy transfer rates via supertransfer.

LH1 complex's natural geometry outperforms randomized geometries by 5.5 standard deviations.

Symmetry plays a crucial role in optimizing light harvesting efficiency.

Abstract

The remarkable rotational symmetry of the photosynthetic antenna complexes of purple bacteria has long been thought to enhance their light harvesting and excitation energy transport. We study the role of symmetry by modeling hypothetical antennas whose symmetry is broken by altering the orientations of the bacteriochlorophyll pigments. We find that in both LH2 and LH1 complexes, symmetry increases energy transfer rates by enabling the cooperative, coherent process of supertransfer. The enhancement is particularly pronounced in the LH1 complex, whose natural geometry outperforms the average randomized geometry by 5.5 standard deviations, the most significant coherence-related enhancement found in a photosynthetic complex.