Tetrasulfonated zinc phthalocyanine (Pc) was bound to graphene (G) sheets by the π-π stacking supermolecular method. The few-layer graphene sheets were obtained by chemically reducing graphite oxide and characterized by AFM, IR and UV-vis absorption methods. Photoinduced electron transfer (PET) within the nano assembly is revealed by laser flash photolysis, time resolved and steady state fluorescence, as well as UV-vis absorption techniques. A graphene sheet can be attached by up to 52,000 Pc molecules to form a super molecule G(Pc)_(52.000), in which many Pc molecules can be simultaneously photoexcited to the S_1 state. One graphene sheet can simultaneously quench thousands of excited Pcs with a large rate constant of the order of 10~(16) M~(-1) s~(-1) by PET. A graphene sheet not only accepts electrons from the excited Pcs on it but also delivers the captured electrons to its unexcited Pcs to form (Pc~·+)_nG(Pc~(·+))n, so that a large electron charge (i.e. n >> 1) is separated between unlinked Pc molecules with a small energy loss. These novel features of PET are explained by the following unique properties of graphene: (i) its excellent electron-transport and multi-electron-accepting ability, (ii) its multi-chromophore binding and concurrent multi-photon absorbing ability.
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机译:采用π-π堆叠超分子法将四磺化锌酞菁(Pc)与石墨烯(G)片结合。通过化学还原氧化石墨制备了几层石墨烯片,并采用AFM、IR和UV-VIS吸收法进行了表征。通过激光闪光光解、时间分辨和稳态荧光以及紫外-可见吸收技术揭示了纳米组件内的光生电子转移 (PET)。石墨烯片可以由多达 52,000 个 Pc 分子附着以形成超级分子 G(Pc)_(52.000),其中许多 Pc 分子可以同时光激发到S_1态。一块石墨烯片可以同时淬灭数千个激发的Pcs,PET的速率常数为10~(16)M~(-1)s~(-1)。石墨烯片不仅接受来自其上激发的Pcs的电子,而且还将捕获的电子传递到其未激发的Pcs中,形成(Pc~·+)_nG(Pc~(·+))n,从而在能量损失较小的未连接的Pc分子之间分离出大的电子电荷(即n >> 1)。PET的这些新特性可以通过石墨烯的以下独特性质来解释:(i)其优异的电子传输和多电子接受能力,(ii)其多发色团结合和并发多光子吸收能力。
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