Over 15% efficient wide-band-gap Cu(In,Ga)S_2 solar cell: Suppressing bulk and interface recombination through composition engineering

Sudhanshu Shukla; Mohit Sood; Damilola Adeleye; Sean Peedle; Gunnar Kusch; Diana Dahliah; Michele Melchiorre; Gian-Marco Rignanese; Geoffroy Hautier; Rachel Oliver; Susanne Siebentritt

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Over 15% efficient wide-band-gap Cu(In,Ga)S_2 solar cell: Suppressing bulk and interface recombination through composition engineering

机译：超过15％的宽带间隙Cu（IN，GA）S_2太阳能电池：抑制通过组成工程的散装和界面重组

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The progress of Cu(In,Ga)S2remains significantly limited mainly due to photovoltage (Voc) losses in the bulk and at the interfaces. Here, via a combination of photoluminescence, cathodoluminescence, electrical measurements, andab initiomodeling, we address the bulk and interface losses to improve ∼1.6-eV-band-gap (Eg) Cu(In,Ga)S2. The optoelectronic quality of the absorber improves upon reducing the [Cu]/[Ga+In] (CGI) ratio, as manifested by the suppression of deep defects, higher quasi-Fermi level splitting (QFLS), improved charge-carrier lifetime, and higher Voc. We identify antisite CuIn/CuGaas a major performance-limiting deep defect by comparing the formation energies of various intrinsic defects. Interface recombination is suppressed using a Zn(O,S) buffer layer in Cu-poor devices, which leads to the activation energy of recombination equal to the Eg. We demonstrate an efficiency of 15.2% with Vocof 902 mV from a H2S-free, Cd-free, and KCN-free process.

机译：Cu（In，Ga）S2的进展显着限制，主要是由于散装和界面处的光伏（VOC）损失。这里，通过光致发光，阴极发光，电测量，Andab onioModeling的组合，我们解决了大量和接口损耗，以改善~1.6-eV带 - 间隙（例如）Cu（In，Ga）S2。吸收体的光电子质量改善了减少[Cu] / [Ga + In]（CGI）的比例，如抑制深缺陷，较高的准Fermi水平分裂（QFL），改进的电荷 - 载体寿命，以及更高的VOC。通过比较各种固有缺陷的形成能量，我们鉴定Antisite Cuin / Cugaas一种主要的性能限制性深度缺陷。使用Cu-差的装置中的Zn（O，S）缓冲层抑制了界面重组，这导致重组的激活能量等于例如Eg。我们向VOCOF提供了15.2％的效率，从H2无H2S，无阳镉和无KCN的过程中。

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来源
《Joule》 |2021年第7期|1816-1831|共16页
作者
Sudhanshu Shukla; Mohit Sood; Damilola Adeleye; Sean Peedle; Gunnar Kusch; Diana Dahliah; Michele Melchiorre; Gian-Marco Rignanese; Geoffroy Hautier; Rachel Oliver; Susanne Siebentritt;
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作者单位

Laboratory for Photovoltaics Department of Physics and Materials Science Research Unit University of Luxembourg;

Laboratory for Photovoltaics Department of Physics and Materials Science Research Unit University of Luxembourg;

Laboratory for Photovoltaics Department of Physics and Materials Science Research Unit University of Luxembourg;

Department of Materials Science and Metallurgy University of Cambridge;

Department of Materials Science and Metallurgy University of Cambridge;

Institute of Condensed Matter and Nanosciences Université catholique de Louvain;

Laboratory for Photovoltaics Department of Physics and Materials Science Research Unit University of Luxembourg;

Institute of Condensed Matter and Nanosciences Université catholique de Louvain;

Institute of Condensed Matter and Nanosciences Université catholique de Louvain|Thayer School of Engineering Dartmouth College;

Department of Materials Science and Metallurgy University of Cambridge;

Laboratory for Photovoltaics Department of Physics and Materials Science Research Unit University of Luxembourg;

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chalcopyrites; photoluminescence; cathodoluminescence; sulfides; DFT; solar cells; bulk and interface recombination; quasi-Fermi level splitting;

机译：Chalcycyites;光致发光;阴极发光;硫化物;DFT;太阳能电池;散装和界面重组;准Fermi水平分裂;

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1. Recombination mechanisms in highly efficient thin film Zn(S,O)/Cu(In,Ga)S_2 based solar cells [J] . S. Merdes, R. Saez-Araoz, A. Ennaoui, Applied Physicsletters . 2009,第21期

机译：高效薄膜Zn（S，O）/ Cu（In，Ga）S_2基太阳能电池的复合机理
2. Compositional engineering of acceptors for highly efficient bulk heterojunction hybrid organic solar cells [J] . Yousaf S. Amber, Ikram M., Ali S. Journal of Colloid and Interface Science . 2018,第期

机译：高效散装异质结杂交有机太阳能电池的构成工程
3. Composition and Interface Engineering for Efficient and Thermally Stable Pb-Sn Mixed Low-Bandgap Perovskite Solar Cells [J] . Chi Dan, Huang Shihua, Zhang Meiying, Advanced Functional Materials . 2018,第51期

机译：高效热稳定的Pb-Sn混合低能隙钙钛矿型太阳能电池的组成和界面工程
4. Theoretical study of the impact of bulk and interface recombination on the performance of GaInP/GaAs/Ge triple junction tandem solar cells [C] . Ghannam, M.Y., Poortmans, . 2003

机译：体和界面复合对GaInP / GaAs / Ge三结串联太阳能电池性能影响的理论研究
5. Development of Highly Efficient and Stable Lead-Free Perovskite Solar Cells Through Composition and Interface Engineering [D] . Tosado, Gabriella A. 2020

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6. Compositional and Interface Engineering of Organic-Inorganic Lead Halide Perovskite Solar Cells [O] . Haizhou Lu, Anurag Krishna, Shaik M. Zakeeruddin, 2020

机译：有机 - 无机铅卤化物钙钛矿太阳能电池的组成和界面工程
7. Perovskite Solar Cells: Interface Engineering of Perovskite/Hole Transport Layer Using Nano‐Network Formation in Small Molecule–Polymer Blend for Efficient Inverted Perovskite Solar Cells (Adv. Mater. Interfaces 6/2021) [O] . Sung Hun Lee, Seungyeon Hong, Hyun Hwi Lee, 2021

机译：Perovskite太阳能电池：钙钛矿/空穴传输层的界面工程，使用小分子 - 聚合物混合物中的纳米网络形成，用于有效倒钙钛矿太阳能电池（ADV。母体。接口6/2021）

Over 15% efficient wide-band-gap Cu(In,Ga)S_2 solar cell: Suppressing bulk and interface recombination through composition engineering

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