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Zhou Cai-bin Li Jing Yi Zhe Ai Hong-jun 《Russian Journal of Physical Chemistry A, Focus on Chemistry》2017,91(10):2044-2051
Russian Journal of Physical Chemistry A - Imidazolium ionic liquids with alanine anion, [C n mim][Ala] (n = 2, 3, 4, 5, 6), were prepared and characterized. The standard addition method was used to... 相似文献
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Modeling Photovoltaic Performances of BTBPD-PC61BM System via Density Functional Theory Calculations
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Cai-bin Zhao Zhi-hua Tang Xiao-hua Guo Hong-guang Ge Jian-qi Ma Wen-liang Wang 《化学物理学报(中文版)》2017,30(3):268-276
Designing and fabricating high-performance photovoltaic devices have remained a major challenge in organic solar cell technologies.In this work,the photovoltaic performances of BTBPD-PC61BM system were theoretically investigated by means of density functional theory calculations coupled with the Marcus charge transfer model in order to seek novel photovoltaic systems.Moreover,the hole-transfer properties of BTBPD thin-film were also studied by an amorphous cell with 100 BTBPD molecules.Results revealed that the BTBPDPC61BM system possessed a middle-sized open-circuit voltage of 0.70 V,large short-circuit current density of 16.874 mA/cm2,large fill factor of 0.846,and high power conversion efficiency of 10%.With the Marcus model,the charge-dissociation rate constant was predicted to be as fast as 3.079×1013 s-1 in the BTBPD-PC61BM interface,which was as 3-5 orders of magnitude large as the decay (radiative and non-radiative) rate constant (108-1010 s-1),indicating very high charge-dissociation efficiency (~100%) in the BTBPD-PC61BM system.Furthermore,by the molecular dynamics simulation,the hole mobility for BTBPD thin-film was predicted to be as high as 3.970×10-3 cm2V-1s-1,which can be attributed to its tight packing in solid state. 相似文献
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采用密度泛函理论(DFT)方法结合不相干的电荷跳跃模型和随机Monte Carlo模拟,研究了2种四噻吩并萘晶体(AT1和AT2)的分子结构、电子性质及电荷载流子传输参数,并预测了这2种晶体室温下空穴和电子迁移率的各向异性.结果表明标题化合物具有近似平面的刚性骨架结构,电荷传输过程中分子的结构弛豫相当小.基于绝热势能面法计算的AT1和AT2分子空穴/电子传输内重组能分别为9.300×10~(-2)/1.100×10~(-1)eV和1.020×10~(-1)/1.290×10~(-1) eV,外重组能分别为1.835×10~(-2)/1.711×10~(-2) eV和1.857×10~(-2)/1.747×10~(-2) eV.利用Monte Carlo随机模拟方法预测的2种分子晶体室温(300K)下空穴/电子迁移率平均值分别为4.976×10~(-3)/2.766×10~(-2) cm~2 V~(-1)s~(-1)和3.857×10~(-3)/1.478×10~(-2)cm~2 V~(-1)s~(-1).此外,迁移率的角度依赖性研究表明2种载流子在AT1和AT2晶体aob平面传输时表现出显著的各向异性,其最大值均沿着电荷传输积分最大的方向,为制备高性能场效应晶体管器件提供了参考. 相似文献
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在水和甲醇的混合液中合成了标题配合物[Co(phendione)(SO4)(H2O)]·5H2O (phendione=1,10-菲啰啉-5,6-二酮),通过元素分析,红外光谱和热分析对配合物进行了表征.结果表明,配合物中Co(Ⅱ)与2个N原子和2个O原子形成4配位结构,其中2个N原子来自配体1,10-菲啰啉-5,6 -二酮,2个O原子分别来自1个水分子和1个硫酸根离子.根据热分解曲线,初步探讨了该配合物的热分解机理,热分解最终产物为CoO. 相似文献
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Designing and fabricating high-performance photovoltaic devices have remained a major challenge in organic solar cell technologies.In this work,the photovoltaic performances of BTBPD-PC61BM system were theoretically investigated by means of density functional theory calculations coupled with the Marcus charge transfer model in order to seek novel photovoltaic systems.Moreover,the hole-transfer properties of BTBPD thin-film were also studied by an amorphous cell with 100 BTBPD molecules.Results revealed that the BTBPDPC61BM system possessed a middle-sized open-circuit voltage of 0.70 V,large short-circuit current density of 16.874 mA/cm2,large fill factor of 0.846,and high power conversion efficiency of 10%.With the Marcus model,the charge-dissociation rate constant was predicted to be as fast as 3.079×1013 s-1 in the BTBPD-PC61BM interface,which was as 3-5 orders of magnitude large as the decay (radiative and non-radiative) rate constant (108-1010 s-1),indicating very high charge-dissociation efficiency (~100%) in the BTBPD-PC61BM system.Furthermore,by the molecular dynamics simulation,the hole mobility for BTBPD thin-film was predicted to be as high as 3.970×10-3 cm2V-1s-1,which can be attributed to its tight packing in solid state. 相似文献
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