Currently, the absorber of CZTSSe solar cells face challenges such as multilayer crystal structure and high bulk defect density, mainly due to their high-speed surface grain growth and high-temperature decomposition. Herein, an effective strategy is proposed to simultaneous promote crystal quality and suppress defect formation by manipulating the heterogeneous redox environment in the CZTS percussor, which balances the crystallization process and CZTSSe phase evolution during absorber growth. With several Cu2+/Sn2+ layers being inserted into the Cu+/Sn4+ precursor, the reduced local surface energy of the percussor enlarges the CZTSSe critical nuclei and decreases its selenization rate, which promote the crystals with more uniform vertical morphology and enlarged lateral size. Concurrently, the extension of phase formation window increases the diffusion of selenium components to the absorber bulk, weakens the decomposition of the CZTSSe film, and thus suppresses the formation of harmful defects CuSn and 2CuZn + SnZn. Consequently, the CZTSSe absorber fabricated using this strategy exhibits a monolayer large-grain structure, achieving an order of magnitude reduction in the defect density, a power conversion efficiency with 14.4 % is attained.
Zhou et al. (Sun,) studied this question.