卤化物
结晶
锡
材料科学
硫化物
化学工程
兴奋剂
硫化铅
SN2反应
离子
退火(玻璃)
无机化学
化学
纳米技术
有机化学
光电子学
冶金
工程类
量子点
作者
Can Gao,Xinyao Wang,Qingyun Yang,Chunxiao Gao,Xiaochun Wang,Xizhe Liu
标识
DOI:10.1021/acs.jpclett.4c02032
摘要
Lead-free perovskite solar cells with hybrid tin halides (Sn-PVKs) as harvesters have attracted attention with respect to eliminating the contamination of conventional hybrid lead halides. However, Sn-PVK films usually have inferior performance due to rapid crystallization and uncontrollable morphology. Moreover, Sn2+ ions suffer from irreversible oxidation that results in self-doping and device instability. Additive engineering is a key strategy for improving the quality of Sn-PVK films, but solid residues of additives could degrade the transport-recombination process. In this work, dipropyl sulfide (DPS) was introduced as a volatile additive into the precursor solution, and no residue exists in the Sn-PVK films after thermal annealing. The coordinating ability of DPS molecules stabilized Sn2+ ions to form the intermediate complex, which retards the crystallization and oxidation of Sn-PVK films. Consequently, the power conversion efficiencies of devices increase from 11.0% to 12.9% with less recombination and a lower leakage current, and the stability of the devices is improved simultaneously.
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