10.3% Efficient Green Cd‐Free Cu<sub>2</sub>ZnSnS<sub>4</sub> Solar Cells Enabled by Liquid‐Phase Promoted Grain Growth
Xiaojie Yuan, Jianjun Li, Jialiang Huang, Chang Yan, Xin Cui, Kaiwen Sun, Jialin Cong, Mingrui He, Ao Wang, Guojun He, Arman Mahboubi Soufiani, Junjie Jiang, Shujie Zhou, John A. Stride, Bram Hoex, Martin A. Green, Xiaojing Hao
Abstract
(CZTS) solar cells. However, forming large grains spanning the absorber layer while maintaining high electronic quality is challenging particularly for pure sulfide CZTS. Herein, a liquid-phase-assisted grain growth (LGG) model that enables the formation of large grains spanning across the CZTS absorber without compromising the electronic quality is demonstrated. By introducing a Ge-alloyed CZTS nanoparticle layer at the bottom of the sputtered precursor, a Cu-rich and Sn-rich liquid phase forms at the high temperature sulfurization stage, which can effectively remove the detrimental near-horizontal grain boundaries and promote grain growth, thus greatly improving the carrier collection efficiency and reducing nonradiative recombination. The remaining liquid phase layer at the rear interface shows a high work function, acting as an effective hole transport layer. The modified morphology greatly increases the short-circuit current density and fill factor, enabling 10.3% efficient green Cd-free CZTS devices. This work unlocks a grain growth mechanism, advancing the morphology control of sulfide-based kesterite solar cells.