Author(s): Wei, B (Wei, Bo); Mao, X (Mao, Xu); Liu, W (Liu, Wen); Ji, CX (Ji, Chunxue); Yang, GQ (Yang, Guiqiang); Bao, YD (Bao, Yidi); Chen, XL (Chen, Xiaoling); Yang, FH (Yang, Fuhua); Wang, XD (Wang, Xiaodong)
Source: PLASMONICS DOI: 10.1007/s11468-023-01902-0 Early Access Date: JUN 2023
Abstract: Light trapping technology is one of the effective ways to improve the performance of solar cells, which can enhance the light absorption and reduce the thickness of the material and thus the expense. In recent years, surface plasmons (SPs) have made considerable progress in this field. By exploiting the light scattering and coupling effects of SPs, the efficiency of solar cells can be improved greatly. The aim of this review is to summarize recent research results of surface plasmon-enhanced GaAs thin-film solar cells, which are technologically mature III-V photovoltaic devices and widely used. Various SP nanostructures employed by different research groups are introduced. It can be concluded that the fabrication method, material, shape, and arrangement of the nanostructures make significant impact on the light trapping effect, as well as the coordination of various SP structures. Key parameters including short-circuit current density (Jsc), open circuit voltage (Voc), power conversion efficiency (PCE), and fill factor (FF) values of typical GaAs thin-film solar cells with different SPs light trapping structures are summarized. Further prospective trends are also proposed for the performance promotion of GaAs solar cells.
Accession Number: WOS:001018110100001
ISSN: 1557-1955
eISSN: 1557-1963