How can the green sulfur bacteria use quantum computing for light harvesting?

TL;DR

This paper explores the potential of quantum computing to explain and model light harvesting in green sulfur bacteria, linking quantum coherence phenomena observed in biological systems and quantum computers.

Contribution

It introduces a novel approach applying quantum computation formalism to understand quantum beats in photosynthetic complexes, bridging biology and quantum physics.

Findings

Quantum coherence persists at physiological temperatures in biological systems.

Quantum computation formalism can model quantum beats in photosynthetic complexes.

Proposes a new perspective on light harvesting mechanisms using quantum computing.

Abstract

Long lasting coherence in photosynthetic pigment-protein complexes has been observed even at physiological temperatures. Experiments have demonstrated quantum coherent behaviour in the long-time operation of the D-Wave quantum computer as well. Quantum coherence is the common feature between the two phenomena. An explanations for eight orders of magnitude discrepancy between the single flux qubit coherence time and the long-time quantum behaviour of an array of thousand flux qubits in the quantum computer was suggested within a theory where the flux qubits are coupled to an environment of particles called gravonons of high density of states The coherent evolution is in high dimensional spacetime and can be understood as a solution of Schroedinger's time-dependent equation. Explanations for the quantum beats observed in 2D Fourier transform electronic spectroscopy of the Fenna-Matthews-Olson (FMO) protein complex in the green sulfur bacteria are presently sought in constructing transport theories based on quantum master equations where 'good' molecular vibrations ('coloured noise') in the chlorophyll and the surrounding protein scaffold knock the exciton oscillations back into coherence. These 'good' vibrations are claimed to have developed in three billion years of natural selection. These theories, however, face the discomforting experimental observation that "attempts to scramble vibrational modes or to shift resonances with isotopic substitution miserably failed to affect the beating signals". As a possible way out of this dilemma we adopted the formalism of the quantum computation to the quantum beats in the FMO protein complex.