AEM:通过氯化锂溶后处理制备浅受体型缺陷Cu2ZnSn(S,Se)4太阳能电池
第一作者:Mingrui He, Xian Zhang, Jialiang Huang
通讯作者:Xiaojing Hao, Jinhyeok Kim, Shiyou Chen, Jianjun Li
合作单位:新南威尔士大学,韩国全南国立大学,华东师范大学,悉尼大学,韩国光州科学技术院
背景介绍
铜锌锡硫硒(CZTSSe)材料由于其低廉的价格,近年来成为薄膜太阳电池研究的热点。然而,在合成CZTSSe过程中伴随着大量晶体缺陷的产生,进而降低了电池的光电转化效率。因此,如何有效调控缺陷是该领域的重要问题。
文章简介
近日,新南威尔士大学Xiaojing Hao团队,韩国全南国立大学Jinhyeok Kim团队和华东师范大学Shiyou Chen团队通过使用氯化锂溶后处理CZTSSe吸收层,实现了更浅的受体型缺陷(LiZn),提高了P型掺杂,将CZTSSe太阳能电池效率提高至10.7%。本文通过纳米尺度的化学分析(atom probe tomography),电学表征分析(admittance spectra)和密度泛函理论(DFT)阐明了Li在CZTSSe掺杂机制。研究表明,通过该方法可实现Li在CZTSSe晶界和晶体内部的均匀掺杂,并实现10%以上的掺杂效率。0.006% 的Li元素掺杂量就能引入1017cm-3的LiZn浅受主缺陷,从而显著改变CZTSSe材料的P-型导电机制和太阳电池器件性能。该成果以题为“High Efficiency Cu2ZnSn(S,Se)4 Solar Cells with Shallow LiZn Acceptor Defects Enabled by Solution-Based Li Post-Deposition Treatment”发表在了Adv. Eng. Mater.上。
图文导读
图一 Li后处理方法
a)-d)LiCl溶液工艺示意图及Li后处理方法
e)未处理的CZTSSe吸收层
f)Li掺杂的CZTSSe吸收层
图二 Li在电池器件的分布
a) CZTSSe和b)锂掺杂的CZTSSe太阳能电池的元素分布
Li在CZTSSe太阳能电池中的3D分布图
图三 电池器件光伏性能
a)电池器件的J-V曲线
b)电池器件的EQE曲线
c)电池器件的带隙
d)电池器件的Drive level capacity profiling
e)电池器件的Suns-Voc
f)电池器件的Time-resolved photoluminescence
图四 缺陷表征
a)-b)电池器件的Admittance spectra
c)电池器件的Arrhenius plots
d)电池器件的缺陷态密度
图五 理论计算
a)不同Li相关缺陷的形成能
b)不同Li相关缺陷在带隙的位置
c)LiZn缺陷在晶格的位置
文献链接:High Efficiency Cu2ZnSn(S,Se)4 Solar Cells with Shallow LiZn Acceptor Defects Enabled by Solution‐Based Li Post‐Deposition Treatment. Adv. Energy Mater. 2021, 2003783.https://doi.org/10.1002/aenm.202003783
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