Open AccessAccumulative Charge Separation Inspired by Photosynthesis
Author(s) -
Susanne Karlsson,
Julien Boixel,
Yann Pellegrin,
Errol Blart,
H.-D. Becker,
Fabrice Odobel,
Leif Hammarström
Publication year - 2010
Publication title -
journal of the american chemical society
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 7.115
H-Index - 612
eISSN - 1520-5126
pISSN - 0002-7863
DOI - 10.1021/ja104809x
Subject(s) - chemistry , artificial photosynthesis , photosynthesis , solar fuel , redox , photoinduced charge separation , photochemistry , photosystem ii , charge (physics) , absorption (acoustics) , photosensitizer , electron , photosynthetic reaction centre , chemical physics , nanotechnology , electron transfer , photocatalysis , optics , organic chemistry , catalysis , physics , biochemistry , materials science , quantum mechanics
Molecular systems that follow the functional principles of photosynthesis have attracted increasing attention as a method for the direct production of solar fuels. This could give a major carbon-neutral energy contribution to our future society. An outstanding challenge in this research is to couple the light-induced charge separation (which generates a single electron-hole pair) to the multielectron processes of water oxidation and fuel generation. New design considerations are needed to allow for several cycles of photon absorption and charge separation of a single artificial photosystem. Here we demonstrate a molecular system with a regenerative photosensitizer that shows two successive events of light-induced charge separation, leading to high-yield accumulation of redox equivalents on single components without sacrificial agents.
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