【摘 要】
:
We think that the current classification of solar cells is not reasonable.We suggest that the first generations should be defined as element (silicon) solar cells,including monocrystalline,multicrysta
【机 构】
:
Eng.Res.Centre of Environment-Friendly Functional Materials for Ministry of Education, Fujian Key La
【出 处】
:
2018第二届全国太阳能材料与太阳能电池学术研讨会
论文部分内容阅读
We think that the current classification of solar cells is not reasonable.We suggest that the first generations should be defined as element (silicon) solar cells,including monocrystalline,multicrystalline,microcrystalline,nanocrystalline,amorphous Si cells;the second generations should be defined as compound solar cells,including CdTe,CIGS,GaAs,CZTSSe cells,etc;the third generations should be hybrid (composite) solar cells,including dye-sensitized cells,perovskite cells,organic cells,quantum dot cells,etc.As two typical examples,perovskite solar cells and dye-sensitized solar cells are introduced.
其他文献
硫化锑(Sb2S3)是一种带隙1.5-1.7eV的直接带隙半导体,环境友好、成本低廉且稳定,是潜在高性能太阳能电池材料.当前硫化锑薄膜太阳能电池仍面临Voc和PCE低的问题,主要与电子提取能力低和深能级缺陷有关.本项目利用单源热蒸发法Sb2S3粉体制备薄膜,通过锂盐掺杂TiO2提高电子传输层对硫化锑吸收层的电子提取性能,使得基于多孔TiO2的硫化锑薄膜太阳能电池的光电转化效率从1.7%提升到了4.
Cu2ZnSnS4 (CZTS) solar cells suffer large open circuit voltage (V∝) deficit comparing to other types of thin film solar cells,such as CdTe and Cu(inxGa1-x)Se2.
本文介绍我们利用金属纳米结构表面等离激元提高有机和钙钛矿太阳能电池效率的研究进展.表面等离激元(SPP)的激发取决于纳米结构的材料、尺寸、形状、密度和周围的电介质环境等参数.通过调控这些参数、设计不同结构的等离激元太阳电池,有望有效利用SPP提升太阳能电池的光电性能.我们通过将AgAl纳米颗粒(NP)嵌入至有机太阳电池的空穴层,显著提升了器件的稳定性和光电转换效率[1].另外,按比率将Au@TiO
铜铟镓硒(Cu(In,Ga) Se2,简称CIGSe)太阳能电池目前光电转化效率,市场占有率,技术成熟度是所有薄膜太阳能电池中最高的,成为了最具商业竞争力的薄膜太阳能电池。但CIGSe电池的大规模生产会大量消耗稀有元素In和Ga,引起电池制造成本的上升从而降低其市场竞争力[1]。将电池吸收层从传统的2~3μm减薄到500 nm以下能大幅度解决稀有元素消耗的问题。同时薄吸收层能降低对吸收层质量的要求