Search results for "Energy quenching"

showing 2 items of 2 documents

In vivo photoprotection mechanisms observed from leaf spectral absorbance changes showing VIS–NIR slow-induced conformational pigment bed changes

2019

Abstract Regulated heat dissipation under excessive light comprises a complexity of mechanisms, whereby the supramolecular light-harvesting pigment–protein complex (LHC) shifts state from light harvesting towards heat dissipation, quenching the excess of photo-induced excitation energy in a non-photochemical way. Based on whole-leaf spectroscopy measuring upward and downward spectral radiance fluxes, we studied spectrally contiguous (hyperspectral) transient time series of absorbance A(λ,t) and passively induced chlorophyll fluorescence F(λ,t) dynamics of intact leaves in the visible and near-infrared wavelengths (VIS–NIR, 400–800 nm) after sudden strong natural-like illumination exposure. …

0106 biological sciences0301 basic medicineChlorophyllMaterials sciencePassive chlorophyll a fluorescencePigment–protein dynamicsLightHyperspectral remote sensingAnalytical chemistryJuglansPlant Science01 natural sciencesBiochemistryEnergy quenchingFluorescenceAbsorbance03 medical and health sciencesTransmittanceFiber Optic TechnologySpectroscopyChlorophyll fluorescencechemistry.chemical_classificationSpectroscopy Near-InfraredAbsorbed photosynthetic active radiation (APAR)Non-photochemical quenching (NPQ)Cell BiologyGeneral MedicineEquipment DesignPigments BiologicalPhotochemical ProcessesCarotenoidsPlant LeavesWavelength030104 developmental biologychemistryXanthophyllRadianceOriginal ArticleAbsorbance shiftMorusControlled heat dissipation010606 plant biology & botanyPhotosynthesis Research
researchProduct

Combined dynamics of the 500–600 nm leaf absorption and chlorophyll fluorescence changes in vivo: Evidence for the multifunctional energy quenching r…

2021

Carotenoids (Cars) regulate the energy flow towards the reaction centres in a versatile way whereby the switch between energy harvesting and dissipation is strongly modulated by the operation of the xanthophyll cycles. However, the cascade of molecular mechanisms during the change from light harvesting to energy dissipation remains spectrally poorly understood. By characterizing the in vivo absorbance changes (Delta A) of leaves from four species in the 500-600 nm range through a Gaussian decomposition, while measuring passively simultaneous Chla fluorescence (F) changes, we present a direct observation of the quick antenna adjustments during a 3-min dark-to-high-light induction. Underlying…

delta-pH0106 biological sciencesBiophysicsxanthophyll cyclesXanthophyllslight-harvesting complex01 natural sciencesBiochemistryFluorescenceEnergy quenchingAbsorbanceabsorbency changes03 medical and health scienceschemistry.chemical_compoundSpectroscopyChlorophyll fluorescenceantheraxanthin030304 developmental biologychemistry.chemical_classification4112 Forestrya fluorescence0303 health sciencesChlorophyll AAntheraxanthincarotenoidsdissipationCell BiologyFluorescencephotoprotectionzeaxanthinchemistrysinglet excited chlaChemical physicsExcited stateXanthophylldynamic quenchingleavesspectral fittinglutein epoxide cycle010606 plant biology & botanyBiochimica et Biophysica Acta (BBA) - Bioenergetics
researchProduct