Статья

Arsenic-Doped CdSeTe Solar Cells Achieve World Record 22.3% Efficiency

Rajni MallickCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USAX. LiCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USAC. ReichCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USAXi ShanCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USAW. ZhangCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USATim NagleCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USALee Jung BokCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USAE. BicakciCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USANathan RosenblattCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USADeepa ModiCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USARouin FarshchiCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USAC. LeeCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USAJames HackCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USASachit GroverCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USANathan R. WolfCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USAWyatt K. MetzgerCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USADe-Long LuCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USAGang XiongCalifornia Technology Center, First Solar Inc., Santa Clara, CA, USA

2023en

ABI

Аннотация

For more than three decades, Cu has been critical to dope CdSeTe solar cells, form effective contacts, and maximize efficiency. At the same time, Cu defect chemistry has limited stability, carrier concentration, and further efficiency improvements. In this article, 22.3% world record efficiency is demonstrated without Cu by implementing As doping, which also improves stability, temperature coefficient, and energy yield. The efficiency crossing point of Group V technology relative to Cu has been driven by steady improvements in the open-circuit voltage. Here, the certified record cell reaches open-circuit voltage of 899 mV while retaining high photocurrent values of 31.4 mA/cm <sup xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">2</sup> ; the fill factor is relatively low at 78.9%. Coupling 80% fill factor with top open-circuit voltage values of 917 mV reported here offers a near-term path to 23% efficiency. Characterization indicates reducing recombination and improving activation provide viable paths to 25% efficiency.

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Идентификаторы

DOI: 10.1109/jphotov.2023.3282581

Цитирования и источники

Цитирований: 3Использованных источников: 0

Показатели — AkademScholar