CHLOROPHYLL ONE‐ELECTRON PHOTOCHEMISTRY: FLASH PHOTOLYSIS STUDIES OF THE CHLOROPHYLL‐QUINONE REACTION IN ALCOHOL SOLVENTS *

— Flash photolysis of chlorophyll a alone in CBE (cyclohexanol‐ t ‐butanol‐ethanol) yields a difference spectrum similar to those obtained upon steady illumination of chlorophyll a ‐quinone mixtures in this solvent. Decay kinetics in CBE and dimethylsulfoxide are faster at the Soret band than at 460–580 nm and red band regions. This difference is not obtained in other solvents (CHCI 3 , CCI 4 , t ‐butanol, ethanol), implying that two or more species are obtained in CBE and DMSO. β‐Carotene in CBE increases the rate of decay of the flash‐induced chlorophyll transients at 430 and 660 nm but only decreases the magnitude of the signal at 470 nm. This implies that the 470 nm absorbance is due to a product formed from the triplet state. This effect is not observed in ethanol. Adding quinone to chlorophyll solutions results in slowly decaying species being generated by flash excitation in CBE. Three components can be distinguished: the first ( t 1/2 ˜ 0.2 msec) corresponds to the triplet state; the second ( t 1/2 = 5–10 msec) is quinone concentration and species independent; the third ( t 1/2 = several seconds) is dependent upon quinone concentration and species (rate is faster for higher concentrations and lower potential quinones). The ESR signal decay rate is approximately equal to the third component flash decay rate when the chlorophyll and quinone concentrations are equal. With excess quinone, the flash decay rate becomes faster, and the ESR decay rate decreases slightly. These slowly‐decaying species are not produced when quinone is added to chlorophyll a in ethanol or t ‐butanol, or to pheophytin in CBE. One observes merely a decrease in signal height with no accompanying increase in decay rate. Mechanisms to account for all of these phenomena are presented which involve an initial chlorophyll triplet‐solvent reaction with the subsequent formation of several species of chloro‐phyll‐quinone radical complexes.