Light-Matter Interactions in Photosynthetic Protein Attached to solids and Nanostructures

TL;DR

This paper reviews recent advancements in hybrid nano-solid-photosynthetic protein devices, focusing on light-matter interactions, energy transfer mechanisms, and plasmonic enhancements for applications like photo-sensing and energy conversion.

Contribution

It provides a comprehensive overview of the mechanisms, device development, and plasmonic effects in solid-state photosynthetic protein systems, highlighting recent progress and future prospects.

Findings

Enhanced absorption and fluorescence due to plasmonic effects

Improved electron transfer efficiency in hybrid devices

Potential applications in photo-sensing and energy conversion

Abstract

The interaction of light with photosynthetic proteins is an extremely efficient process and has been thoroughly investigated. However, exploring light-matter interactions in hybrid nano-solid-photosynthetic proteins is a relatively new and existing field of research. The properties of these hybrid materials significantly influence the energy levels, non-radiative energy transfer, absorption, and fluorescence of the photosynthetic proteins upon interaction with light. There is special interest in levering these light-matter interactions for applications such as photo-sensing and converting light energy to electricity. The development of efficient devices requires the formation of a junction for oriented attachment, facilitating efficient energy and electronic transfer between the solids and the proteins. This review will outline the major advancements in solid-state photosynthetic protein devices, elucidate the underlying mechanism, and assess electron transfer efficiency. Furthermore, it will explore and analyze the effect of plasmons on the enhancement of absorption, fluorescence, and photocurrent in hybrid devices.