Primary charge separation and energy transfer in the photosystem I reaction center of higher plants

White, N T.H.; Beddard, G S; R G, Thorne J; Feehan, T M; Keyes, T E; Heathcote, P

doi:10.1021/jp9604709

Title: Primary charge separation and energy transfer in the photosystem I reaction center of higher plants

Journal Article · Thu Jul 18 00:00:00 EDT 1996 · Journal of Physical Chemistry

DOI:https://doi.org/10.1021/jp9604709· OSTI ID:380814

White, N T.H.; Beddard, G S; R G, Thorne J; Feehan, T M; Keyes, T E ^[1]; Heathcote, P ^[2]

Univ. of Manchester (United Kingdom)
Queen Mary and Westfield College, London (United Kingdom)

Using low intensity femtosecond duration laser pulses at 708 nm, we have observed absorption transients associated with electron transfer through the primary electron acceptor A{sub 0} in the photosystem I (PSI) reaction center from spinach under nonreducing conditions. At this wavelength the electron donor P{sub 700} is excited directly, although some antenna chlorophylls are also excited. Using a nanosecond duration preflash of 690 nm to oxidize P{sub 700}, and then measuring the absorption transients from the antenna alone, it is possible by subtraction to isolate the absorption transients arising from electron transfer. We discuss this method critically. Th spectrum of A{sub 0}{sup -}-A{sub 0} does not appear promptly but takes nearly 3 ps to reach maximum intensity and resembles those spectra previously obtained from higher plants, with a maximum bleaching at 685{+-}2 nm and a shoulder in the region 670-675 nm. The decay time of the primary radical pair P{sub 700}{sup +}A{sub 0}{sup -} is calculated as 20 ps. Analysis of absorption transients indicates that the intrinsic rate constant forming the primary radical pair P{sub 700}{sup +}A{sub 0}{sup -} cannot be measured directly because energy migration in the antenna is fast and quenching is approaching `trap limited` behavior. With use of a detailed model of the antenna energy migration based on the X-ray structure, the intrinsic rate constant for electron transfer is estimated as k{sub 1} nearly equals 0.7 ps{sup -1}. 81 refs., 15 figs., 1 tab.

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OSTI ID:: 380814

Journal Information:: Journal of Physical Chemistry, Vol. 100, Issue 29; Other Information: PBD: 18 Jul 1996

Country of Publication:: United States

Language:: English

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55 BIOLOGY AND MEDICINE
BASIC STUDIES
40 CHEMISTRY
66 PHYSICS
14 SOLAR ENERGY
PHOTOSYNTHETIC REACTION CENTERS
ENERGY TRANSFER
ABSORPTION SPECTRA
ELECTRON TRANSFER
CHEMICAL REACTION KINETICS
PHOTOSYNTHESIS
PLANTS
MATHEMATICAL MODELS
CHARGE TRANSPORT

Title: Primary charge separation and energy transfer in the photosystem I reaction center of higher plants

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