Modelling excitonic energy transfers in Bryopsis corticulans using 2D electronic spectroscopy

We apply a phenomenological fitting method to the two-dimensional electronic spectra of the light-harvesting complex II (LHCII) from Bryopsis corticulans (B. corticulans) at 77 K to extract information about the excitonic states and energy transfer processes. B. corticulans is a marine green alga wh...

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Main Authors: Nguyen, H. L., Do, T. N., Akhtar, P., Jansen, T. L. C., Knoester, J., Lambrev, P. H., Tan, H. S.
Other Authors: Asian Spectroscopy Conference 2020
Format: Conference or Workshop Item
Language:English
Published: 2020
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Online Access:https://hdl.handle.net/10356/144301
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Institution: Nanyang Technological University
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spelling sg-ntu-dr.10356-1443012020-10-29T20:11:02Z Modelling excitonic energy transfers in Bryopsis corticulans using 2D electronic spectroscopy Nguyen, H. L. Do, T. N. Akhtar, P. Jansen, T. L. C. Knoester, J. Lambrev, P. H. Tan, H. S. Asian Spectroscopy Conference 2020 Institute of Advanced Studies Science::Chemistry Photosynthesis Light Harvesting Complexes We apply a phenomenological fitting method to the two-dimensional electronic spectra of the light-harvesting complex II (LHCII) from Bryopsis corticulans (B. corticulans) at 77 K to extract information about the excitonic states and energy transfer processes. B. corticulans is a marine green alga whose photosynthesis adapts to the underwater environment; thus, its properties are expected to deviate from the widely studied plant LHCII to some extent. The fitting method results in well converged parameters, including eight excitonic energy levels with their respective transition dipole moments, spectral widths, energy transfer rates and coupling properties. The 2D spectra simulated from the fitted parameters concur very well with the experimental data, proving the robustness of the fitting method. An excitonic energy transfer scheme can be constructed from the fitting parameters, which is described for the first-time for B. corticulans LHCII. The strength of our phenomenological fitting method in obtaining excitonic energy levels and energy transfer network is put to good test in systems such as B. corticulans LHCII where prior knowledge and exact assignment and spatial locations of pigments are lacking. We hope future full structural determination of B. corticulans LHCII can validate our predictions. Published version 2020-10-27T07:50:57Z 2020-10-27T07:50:57Z 2020 Conference Paper Nguyen, H. L., Do, T. N., Akhtar, P., Jansen, T. L. C., Knoester, J., Lambrev, P. H.S. K. (2020). Modelling excitonic energy transfers in Bryopsis corticulans using 2D electronic spectroscopy. Proc. Of the 7th Asian Spectroscopy Conference (ASC 2020). doi:10.32655/ASC_8-10_Dec2020.46 https://hdl.handle.net/10356/144301 10.32655/ASC_8-10_Dec2020.46 en © 2020 Nanyang Technological University. application/pdf
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic Science::Chemistry
Photosynthesis
Light Harvesting Complexes
spellingShingle Science::Chemistry
Photosynthesis
Light Harvesting Complexes
Nguyen, H. L.
Do, T. N.
Akhtar, P.
Jansen, T. L. C.
Knoester, J.
Lambrev, P. H.
Tan, H. S.
Modelling excitonic energy transfers in Bryopsis corticulans using 2D electronic spectroscopy
description We apply a phenomenological fitting method to the two-dimensional electronic spectra of the light-harvesting complex II (LHCII) from Bryopsis corticulans (B. corticulans) at 77 K to extract information about the excitonic states and energy transfer processes. B. corticulans is a marine green alga whose photosynthesis adapts to the underwater environment; thus, its properties are expected to deviate from the widely studied plant LHCII to some extent. The fitting method results in well converged parameters, including eight excitonic energy levels with their respective transition dipole moments, spectral widths, energy transfer rates and coupling properties. The 2D spectra simulated from the fitted parameters concur very well with the experimental data, proving the robustness of the fitting method. An excitonic energy transfer scheme can be constructed from the fitting parameters, which is described for the first-time for B. corticulans LHCII. The strength of our phenomenological fitting method in obtaining excitonic energy levels and energy transfer network is put to good test in systems such as B. corticulans LHCII where prior knowledge and exact assignment and spatial locations of pigments are lacking. We hope future full structural determination of B. corticulans LHCII can validate our predictions.
author2 Asian Spectroscopy Conference 2020
author_facet Asian Spectroscopy Conference 2020
Nguyen, H. L.
Do, T. N.
Akhtar, P.
Jansen, T. L. C.
Knoester, J.
Lambrev, P. H.
Tan, H. S.
format Conference or Workshop Item
author Nguyen, H. L.
Do, T. N.
Akhtar, P.
Jansen, T. L. C.
Knoester, J.
Lambrev, P. H.
Tan, H. S.
author_sort Nguyen, H. L.
title Modelling excitonic energy transfers in Bryopsis corticulans using 2D electronic spectroscopy
title_short Modelling excitonic energy transfers in Bryopsis corticulans using 2D electronic spectroscopy
title_full Modelling excitonic energy transfers in Bryopsis corticulans using 2D electronic spectroscopy
title_fullStr Modelling excitonic energy transfers in Bryopsis corticulans using 2D electronic spectroscopy
title_full_unstemmed Modelling excitonic energy transfers in Bryopsis corticulans using 2D electronic spectroscopy
title_sort modelling excitonic energy transfers in bryopsis corticulans using 2d electronic spectroscopy
publishDate 2020
url https://hdl.handle.net/10356/144301
_version_ 1683493466108067840