PHOTOCHEMICAL AND SPECTRAL PROPERTIES OF A PARTICULATE MODEL SYSTEM OF CHLOROPHYLL WITH AMPHIPHILES PREPARED FROM HISTAMINE

Abstract

— In the photosynthesis model system described, chlorophyll a at an interface photosensitizes the transfer of hydrogen equivalents from a hydrocarbon phase to an aqueous phase. The hydrocarbon phase, to which chlorophyll is adsorbed, consists of polyethylene particles swollen with tetradecane. The particles are also charged positive by co-adsorption of dodecylpyridinium iodide. Furthermore, chlorophyll is ligated with the imidazole function of one of several amphiphiles derived from histamine, which may or may not contain a reducible nitroaromatic group that can serve as primary electron acceptor from photoexcited chlorophyll. The fluorescence quantum yield of chlorophyll on these particles is diminished by self-association of the pigment and by reaction with an oxidizing amphiphile; in the latter case, the quantum yield is correlated with the one-electron redox potential of the amphiphile. Fluorescence-lifetime analysis reveals that most excited singlet states of chlorophyll are quenched rather quickly, and that most of the fluorescence comes from a small fraction of chlorophyll with long lifetime. All preparations sensitize the photoreduction of 5,5′-dithiobis(2-nitrobenzoate) (DTNB) to the water-soluble thiolate by hydrazobenzene. When the amphiphile that ligates chlorophyll is not oxidizing, the quantum yield of photoreduction is unrelated to the fluorescence yield of the particles, but may be related to the degree of self-association of chlorophyll. When the amphiphile that ligates chlorophyll is oxidizing, the kinetics of photoreduction of DTNB require that the electron passes through the primary oxidant to DTNB. Quantum yields for photosensitized reducton of oxidizing amphiphiles in the absence of DTNB have a reversed correlation with redox potential, which can be rationalized in terms of the Marcus theory of electron transfer. All data are most consistently accounted for if the primary photoproduct is an ion pair of chlorophyll and primary oxidant when the latter is available, and a chlorophyll radical ion pair when it is not, both formed by electron transfer from the singlet excited state of chlorophyll.