Measuring Photonics in Photosynthesis: Combined Micro-Fourier Image Spectroscopy and Pulse Amplitude Modulated Chlorophyll Fluorimetry at the Micrometre-Scale

Natural photonic structures are common across the biological kingdoms, serving a diversity of functionalities. The study of implications of photonic structures in plants and other phototrophic organisms is still hampered by missing methodologies for determining in situ photonic properties, particula...

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Published in:Biomimetics (Basel, Switzerland) Switzerland), 2022-08, Vol.7 (3), p.107
Main Authors: Wardley, William P., Goessling, Johannes W., Lopez-Garcia, Martin
Format: Article
Language:English
Subjects:
Acclimation
Begonia sp
Chlorophyll
diatoms
Energy
Light
Methods
natural photonics
PAM fluorimetry
Photonics
Photosynthesis
Plankton
Silica
Spectroscopy
Spectrum analysis
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creator Wardley, William P.
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description Natural photonic structures are common across the biological kingdoms, serving a diversity of functionalities. The study of implications of photonic structures in plants and other phototrophic organisms is still hampered by missing methodologies for determining in situ photonic properties, particularly in the context of constantly adapting photosynthetic systems controlled by acclimation mechanisms on the cellular scale. We describe an innovative approach to determining spatial and spectral photonic properties and photosynthesis activity, employing micro-Fourier Image Spectroscopy and Pulse Amplitude Modulated Chlorophyll Fluorimetry in a combined microscope setup. Using two examples from the photosynthetic realm, the dynamic Bragg-stack-like thylakoid structures of Begonia sp. and complex 2.5 D photonic crystal slabs from the diatom Coscinodiscus granii, we demonstrate how the setup can be used for measuring self-adapting photonic-photosynthetic systems and photonic properties on single-cell scales. We suggest that the setup is well-suited for the determination of photonic–photosynthetic systems in a diversity of organisms, facilitating the cellular, temporal, spectral and angular resolution of both light distribution and combined chlorophyll fluorescence determination. As the catalogue of photonic structure from photosynthetic organisms is rich and diverse in examples, a deepened study could inspire the design of novel optical- and light-harvesting technologies.
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subjects Acclimation
Begonia sp
Chlorophyll
diatoms
Energy
Light
Methods
natural photonics
PAM fluorimetry
Photonics
Photosynthesis
Plankton
Silica
Spectroscopy
Spectrum analysis
title Measuring Photonics in Photosynthesis: Combined Micro-Fourier Image Spectroscopy and Pulse Amplitude Modulated Chlorophyll Fluorimetry at the Micrometre-Scale
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