# Non-reciprocal Light-harvesting Nanoantennae Made by Nature

**Authors:** Julian Juhi-Lian Ting

arXiv: 1702.06671 · 2019-04-09

## TL;DR

This paper extends classical radio-antenna theory to the optical regime to explain the non-reciprocal properties of bacterial light-harvesting structures, providing insights for designing advanced optical devices.

## Contribution

It offers a physical explanation of bacterial light-harvesting mechanisms using non-reciprocal antenna models, linking biological structures to optical physics and potential technological applications.

## Key findings

- Explained the role of non-heme iron in reaction centers.
- Analyzed the toroidal shape and size limits of light harvesters.
- Identified mechanisms used by radiation-resistant bacteria.

## Abstract

Most of our current understanding of mechanisms of photosynthesis comes from spectroscopy. However, classical definition of radio-antenna can be extended to optical regime to discuss the function of light-harvesting antennae. Further to our previously proposed model of a loop antenna we provide several more physical explanations on considering the non-reciprocal properties of the light harvesters of bacteria. We explained the function of the non-heme iron at the reaction center, and presented reasons for each module of the light harvester being composed of one carotenoid, two short $\alpha$-helical polypeptides and three bacteriochlorophylls; we explained also the toroidal shape of the light harvester, the upper bound of the characteristic length of the light harvester, the functional role played by the long-lasting spectrometric signal observed, and the photon anti-bunching observed. Based on these analyses, two mechanisms might be used by radiation-durable bacteria, {\it Deinococcus radiodurans}; and the non-reciprocity of an archaeon, {\it Haloquadratum walsbyi}, are analyzed. The physical lessons involved are useful for designing artificial light harvesters, optical sensors, wireless power chargers, passive super-Planckian heat radiators, photocatalytic hydrogen generators, and radiation protective cloaks. In particular it can predict what kind of particles should be used to separate sunlight into a photovoltaically and thermally useful range to enhance the efficiency of solar cells.

## Full text

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## Figures

8 figures with captions in the complete paper: https://tomesphere.com/paper/1702.06671/full.md

## References

100 references — full list in the complete paper: https://tomesphere.com/paper/1702.06671/full.md

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Source: https://tomesphere.com/paper/1702.06671