机构地区:[1]Key Laboratory of Novel Thin Film Solar Cells,Institute of Applied Technology,Hefei Institutes of Physical Science,Chinese Academy of Sciences [2]Beijing Key Lab of Novel Thin Film Solar Cells,North China Electric Power University
出 处:《Science China Materials》2015年第6期447-454,共8页中国科学(材料科学(英文版)
基 金:financially supported by the National Basic Research Program of China (2011CBA00700);External Cooperation Program of Chinese Academy of Sciences (GJHZ1220);the National High Technology Research and Development Program of China (2011AA050510);the National Natural Science Foundation of China (21103197, 21173227, 21403247, 61404142 and 21273242);the Program of Hefei Center for Physical Science and Technology (2012FXZY006)
摘 要:A novel supramolecular gel electrolyte formed from two-component low molecular mass organogelators was developed and introduced into quasi-solid-state dye sensitized solar cell(QS-DSSC). This supramolecular gel electrolyte system was prepared by using N,N?-1,5-pentanediylbis-dodecanamide and 4-(Boc-aminomethyl)pyridine as co-gelator. Furthermore, the morphologies of the two-component supramolecular gel electrolyte and single-component gel electrolyte were observed by the polarized optical light microscopy, and the charge transport property of the two-component supramolecular gel electrolyte and the kinetic processes of the electron transport/recombination were investigated by the intensity-modulated photocurrent spectroscopy/intensity-modulated photovoltage spectroscopy(IMPS/IMVS). The polarized optical microscopy(POM) revealed that the single-component gel electrolyte was formed as the rod-like fibers, whereas the fibers changed to branched structure in the two-component supramolecular gel electrolyte. Moreover, comparing with the single-component gel electrolyte based QS-DSSC, the electron transport is faster and the electron recombination at the Ti O2/electrolyte interface is slower in the two-component supramolecular gel electrolyte based QSDSSC. Consequently, an efficiency of 7.04% was obtained by the two-component supramolecular gel electrolyte based QSDSSC, which is higher than that of the single-component gel electrolyte based QS-DSSC(6.59%).本文制备了一种由N,N?-1,5-戊二基双月桂酰胺和4-(Boc-氨基甲基)吡啶作为共胶凝剂的新型超分子凝胶电解质,并将其应用于准固态染料敏化太阳电池(QS-DSSC)中.通过偏光显微镜观察超分子凝胶电解质和由N,N?-1,5-戊二基双月桂酰胺制备的单组份凝胶电解质微观形貌的差异,并通过调制光电流谱/调制光电压谱(IMPS/IMVS)来研究两种凝胶电解质体系中的电子传输/复合动力学过程.结果表明,单组份凝胶电解质中的网络结构是由棒状纤维构成,而在超分子凝胶电解质中出现分叉纤维结构;与单组份凝胶电解质组装的QS-DSSC相比,基于超分子凝胶电解质的QS-DSSC内部电子传输更快且电子在Ti O2/电解质界面处的复合速率更慢.最终,基于超分子凝胶电解质的QS-DSSC获得了7.04%的光电转换效率,高于基于单组份凝胶电解质的QS-DSSC的光电转换效率(6.59%).
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