| 选择性合成不同形貌的Sb2S3纳米结构应用于高性能的染料敏化太阳能电池(英文) |
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| 引用本文: | 陈学,李雪敏,卫朋坤,马小勇,喻其林,刘璐.选择性合成不同形貌的Sb2S3纳米结构应用于高性能的染料敏化太阳能电池(英文)[J].催化学报,2020(3):435-441. |
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| 作者姓名: | 陈学 李雪敏 卫朋坤 马小勇 喻其林 刘璐 |
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| 作者单位: | 南开大学环境科学与工程学院环境修复与污染控制天津重点实验室;南开大学生命科学学院分子微生物与技术重点实验室;山西省环境科学研究院 |
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| 基金项目: | funded by the Tianjin science and technology support key projects(18YFZCSF00500);the National Science Fund for Distinguished Young Scholars(21425729);the National Natural Science Foundation of China |
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| 摘 要: | 近几十年来,随着全球变暖和能源危机的日益严重,对取之不尽、用之不竭的清洁能源技术的需求越来越迫切.1991年Gratzel首次报道了染料敏化太阳能电池(DSSCs),它以低廉的价格、优异的理论功率转换效率(PCE)、环保、多色透明等优点而引起了研究者的关注.Sb2S3因其1.5-2.2 eV的间隙宽度被认为是最有前途的对电极材料之一.此外,Sb2S3是地球中含量丰富的无毒锑矿物的主要成分,还被广泛应用于太阳能转换材料、催化剂、光导探测器等领域.众所周知,石墨烯具有巨大的比表面积、显著的载流子迁移率和优异的热/化学稳定性,这使得提高电子转移效率和电催化活性成为可能.首先,采用改进的Hummers方法制备了氧化石墨烯纳米片;然后采用水热法通过改变Sb源以及实验pH值,合成了Sb2S3和Sb2S3@RGO样品.对样品进行X射线粉末衍射(XRD)、扫描电子显微镜镜(SEM)、投射电子显微镜(TEM)以及比表面积表征.结果表明,在Sb源不变的情况下,Sb2S3样品的形貌随pH值的变化而变化.以三乙酸锑为Sb源,在pH=3时,Sb2S3的形貌类似于一个完整的纳米棒结构;在pH值为6时,样品为不规则球体;当pH值为8时,纳米片结构开始出现;但当p H=10时,纳米片结构并不均匀.根据XRD分析,只有当pH值为3时,样品的衍射峰才与标准卡(JCPDS42-1393)的衍射峰一致.当以氯化锑作为锑源,样品的形貌由不规则的杆状(pH=3)转变为纳米球(pH=6),然后出现纳米片结构(pH=8).不同的是,当p H值为10时,纳米薄片形成均一的花状结构.XRD结果表明,除pH值为3外,样品的衍射峰与标准卡(JCPDS42-1393)的值吻合较好.结果表明,合成条件所需的Sb源和碱性环境是合成具有均匀花状结构的纳米片状Sb2S3所必不可少的.测得Sb2S3的比表面积约为41.72 m^2g^-1,平均孔径为31.08nm,Sb2S3@RGO的分别为44.53 m^2g^-1和22.65 nm.Sb2S3和Sb2S3@RGO复合材料均具有介孔结构,为内部电催化剂提供了广阔的通道,从而提高了对电极的催化能力,促进了电化学反应.将Sb2S3纳米花球和Sb2S3@RGO纳米薄片作为染料敏化太阳能电池的对电极进行了测试,由于石墨烯的引入,后者比前者具有更好的电催化性能.电化学实验结果表明,与Sb2S3,RGO,Pt作为对电极相比,制备的Sb2S3@RGO纳米薄片具有更好的催化活性、电荷转移能力和电化学稳定性,Sb2S3@RGO的功率转换效率达到8.17%,优于标准Pt对电极(7.75%).
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| 关 键 词: | Sb2S3 还原性石墨烯 对电极 染料敏化电池 功率转换效率 |
Selective synthesis of Sb2S3 nanostructures with different morphologies for high performance in dye-sensitized solar cells |
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| Xue Chen,Xuemin Li,Pengkun Wei,Xiaoyong Ma,Qinlin Yu,Lu Liu.Selective synthesis of Sb2S3 nanostructures with different morphologies for high performance in dye-sensitized solar cells[J].Chinese Journal of Catalysis,2020(3):435-441. |
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| Authors: | Xue Chen Xuemin Li Pengkun Wei Xiaoyong Ma Qinlin Yu Lu Liu |
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| Institution: | (Tianjin Key Laboratory of Environmental Remediation and Pollution Control,College of Environmental Science and Engineering,Nankai University,Tianjin 300350,China;Key Laboratory of Molecular Microbiology and Technology,College of Life Science,Nankai University,Tianjin 300350,China;Shanxi Provincial Research Academy of Environmental Sciences,Taiyuan 030027,Shanxi) |
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| Abstract: | In this work,we initially synthesized Sb2S3 with uniform flower-like structures via a facile hydrothermal method through the modification of the Sb source and pH value.Afterward,Sb2S3 with a nanosheet structure was successfully synthesized on reduced graphene oxide(Sb2S3@RGO).The flower-like Sb2S3 and the Sb2S3@RGO nanosheets were tested as the counter electrode(CE)of dye-sensitized solar cells,and the latter exhibited a higher electrocatalytic property than the former owing to the introduction of graphene.The results from electrochemical tests indicated that the as-prepared Sb2S3@RGO nanosheets possess higher catalytic activity,charge-transfer ability,and electrochemical stability than Sb2S3,RGO,and Pt CEs.More notably,the power conversion efficiency of Sb2S3@RGO reached 8.17%,which was higher than that of the standard Pt CE(7.75%). |
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| Keywords: | Sb2S3 Reduced graphene oxide Counter electrode Dye-sensitized cells Power conversion efficiency |
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