Spectroscopic studies on origination of the peak at 730 nm in delayed fluorescence of chloroplasts

Zeng, Lizhang; Xing, Da; Zhang, Lingrui; Li, Qiang; Wang, Chenglong

doi:10.1002/bio.978

Cited by 4 publications

(2 citation statements)

References 24 publications

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“…The fluorescence spectrum detection system used for these experiments was an LS‐55 Luminescence Spectrometer (Fluorescence Mode) (Perkin‐Elmer, USA) . A diagram of the system is shown in Scheme S1.…”

Section: Methodsmentioning

confidence: 99%

Spectral analysis on origination of the bands at 437 nm and 475.5 nm of chlorophyll fluorescence excitation spectrum in Arabidopsis chloroplasts

2015

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Chlorophyll fluorescence has been often used as an intrinsic optical molecular probe to study photosynthesis. In this study, the origin of bands at 437 and 475.5 nm in the chlorophyll fluorescence excitation spectrum for emission at 685 nm in Arabidopsis chloroplasts was investigated using various optical analysis methods. The results revealed that this fluorescence excitation spectrum was related to the absorption characteristics of pigment molecules in PSII complexes. Moreover, the excitation band centred at 475.5 nm had a blue shift, but the excitation band at 437 nm changed relatively less due to induction of non-photochemical quenching (NPQ). Furthermore, fluorescence emission spectra showed that this blue shift occurred when excitation energy transfer from both chlorophyll b (Chl b) and carotenoids (Cars) to chlorophyll a (Chl a) was blocked. These results demonstrate that the excitation band at 437 nm was mainly contributed by Chl a, while the excitation band at 475.5 nm was mainly contributed by Chl b and Cars. The chlorophyll fluorescence excitation spectrum, therefore, could serve as a useful tool to describe specific characteristics of light absorption and energy transfer between light-harvesting pigments.

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Section: Methodsmentioning

confidence: 99%

Spectral analysis on origination of the bands at 437 nm and 475.5 nm of chlorophyll fluorescence excitation spectrum in Arabidopsis chloroplasts

2015

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“…Photosynthetic chlorophyll, for example, is one of the most intelligent light-harvesters in nature123; it has two characteristic absorption bands at the blue and red regions, matching the maximal energy flux and near maximal photon flux of sunlight, respectively345. Considerable efforts have been devoted to investigating the underlying mechanisms of light-harvesting of the chlorophyll molecules15678910 and to exploring ways to broaden their absorption regions456111213 with the objective of further improving their overall light-harvesting efficiency for photovoltaic and photosynthetic applications.…”

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confidence: 99%

Plasmon-Enhanced Light Harvesting of Chlorophylls on Near-Percolating Silver Films via One-Photon Anti-Stokes Upconversion

Wang

Nan

Liu

et al. 2013

Sci Rep

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There exists a wealth of means of efficient utilization of solar energy in nature, with photosynthesis of chlorophylls as a prime example. Separately, artificially structured plasmonic materials are versatile in light harvesting and energy conversion. Using a simple and scalable design of near-percolating silver nanostructures, we demonstrate that the light-harvesting efficiency of chlorophylls can be drastically enhanced by tuning the plasmon frequency of the constituent silver nanoparticles to coincide with the maximal photon flux of sunlight. In particular, we show that the photon upconversion efficiency can be readily enhanced by over 20 folds, with the room-temperature fluorescence quantum yield increased by a factor of 2.63. The underlying mechanism for the upconversion enhancement is attributed to a one-electron-per-photon anti-Stokes process, involving absorption of a characteristic phonon mode of the chlorophylls. These findings suggest that chlorophylls can serve as molecular building blocks for high-efficiency light harvesting and solar energy conversion.

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Delayed fluorescence spectra of intact leaves photoexcited by sunlight measured with a multichannel Fourier-transform chemiluminescence spectrometer

Akita

Yano

Ishii³

et al. 2013

Chemical Physics Letters

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Spectroscopic studies on origination of the peak at 730 nm in delayed fluorescence of chloroplasts

Cited by 4 publications

References 24 publications

Spectral analysis on origination of the bands at 437 nm and 475.5 nm of chlorophyll fluorescence excitation spectrum in Arabidopsis chloroplasts

Spectral analysis on origination of the bands at 437 nm and 475.5 nm of chlorophyll fluorescence excitation spectrum in Arabidopsis chloroplasts

Plasmon-Enhanced Light Harvesting of Chlorophylls on Near-Percolating Silver Films via One-Photon Anti-Stokes Upconversion

Delayed fluorescence spectra of intact leaves photoexcited by sunlight measured with a multichannel Fourier-transform chemiluminescence spectrometer

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