From coherent to vibronic light harvesting in photosynthesis

•The evolving understanding of quantum effects in photosynthesis is reviewed.•2D spectroscopy and the spectral signatures that differentiate electronic/vibrational from vibronic coherences are presented.•A vibronic model is described to demonstrate how quantum effects can optimize energy transfer.•V...

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Bibliographic Details
Published in:Current opinion in chemical biology 2018-12, Vol.47, p.39-46
Main Authors: Jumper, Chanelle C, Rafiq, Shahnawaz, Wang, Siwei, Scholes, Gregory D
Format: Article
Language:English
Subjects:
BASIC BIOLOGICAL SCIENCES
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Summary:•The evolving understanding of quantum effects in photosynthesis is reviewed.•2D spectroscopy and the spectral signatures that differentiate electronic/vibrational from vibronic coherences are presented.•A vibronic model is described to demonstrate how quantum effects can optimize energy transfer.•Vibronic coupling can modify the Förster rate through intensity redistribution of transitions involved in the spectral overlap. Photosynthetic organisms are a remarkable example of nanoscale engineering and have mastered the process of solar energy harvesting over billions of years of evolution. Therefore, researchers seek insights from the light collection mechanisms of photosynthetic machinery. The initial energy transfer stage of photosynthesis, which begins with light absorption and leads to charge separation, is remarkably robust in conditions of strong energetic disorder, extreme physiological temperatures, and low light flux — very different from conventional solar conversion materials [1–3]. However, determining the key principles which are responsible for efficient conversion is a challenging task due to the complexity of the photosynthetic systems. The field encountered a fascinating lead in 2007 when oscillatory features were discovered in two-dimensional electronic spectroscopic data — the optical analogue of 2D NMR — and were assigned to quantum coherence between donor and acceptor electronic states [4••]. In this review, we describe the evolution in our understanding of quantum effects in photosynthetic energy transfer. A vibronic model is described to demonstrate the current opinion on how quantum effects can optimize energy transfer.
ISSN:1367-5931
1879-0402
DOI:10.1016/j.cbpa.2018.07.023