材料科学
钝化
串联
量子点
硫化铅
空位缺陷
光电子学
纳米晶
离子
光伏
纳米技术
钙钛矿(结构)
能量转换效率
量子效率
原位
捷克先令
化学计量学
光致发光
锌黄锡矿
二极管
硫化镉
三卤化物
纳米颗粒
工作职能
硫化物
太阳能电池
光电探测器
硫黄
化学工程
油胺
钙钛矿太阳能电池
发光二极管
硫化锌
光化学
作者
Afei Zhang,Yì Wáng,Salman Ali,Gomaa Mohamed Gomaa Khalaf,Xinzhao Zhao,Michael Wang,Chris Cheng,Jianbing Zhang,Kun Xu,L Wang,Hsien‐Yi Hsu,Haisheng Song,Mingyu Li
摘要
ABSTRACT Efficient narrow‐bandgap PbS quantum dot (QD) solar cells are promising candidates for bottom subcells in multi‐junction tandem photovoltaics. However, solution‐phase ligand exchange inevitably disrupts surface stoichiometry by introducing sulfur vacancies and excess lead iodide (PbI 2 ), which could act as non‐radiative recombination sites and ion migration pathways. Herein, we develop an in situ sulfur‐supplementation strategy utilizing N,N ‐Diphenylthiourea (DPTU). In the butylamine‐mediated alkaline environment, DPTU releases sulfide ions that spontaneously repair sulfur vacancies and scavenge excess PbI 2 . Driven by the significant difference in solubility product constants between PbS and PbI 2 in N,N ‐Dimethylformamide, this process produces stoichiometric PbS ink with suppressed defect density. Combined with vacuum‐assisted annealing, the 0.95 eV PbS QD devices achieve a record efficiency of 14.34% and a silicon‐filtered efficiency of 1.56%, with excellent near‐infrared photodetector performance and aging stability. Furthermore, optimized PbS devices contributed additional efficiencies of 6.37%, 2.56%, and 2.22% beneath 1.77, 1.26, and 1.77/1.26 eV perovskite filters, respectively. This work offers a robust in situ bulk passivation strategy to suppress vacancy defects and ion migration in PbS QD photovoltaics, paving the way for their application in high‐performance tandem solar cells.
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