Affiliation:
1. info-Powered Energy System Research Center (i-PERC) The University of Electro-Communications Tokyo 182-8585 Japan
2. State Key Laboratory of Photovoltaic Science and Technology Shanghai Frontiers Science Research Base of Intelligent Optoelectronics and Perception Department of Materials Science Institute of Optoelectronics Fudan University Shanghai 200433 China
Abstract
AbstractNontoxic Sn‐based perovskite solar cells (PSCs) represent a promising alternative to Pb‐based PSCs, given their similar electronic properties and an ideal bandgap, accompanied by the highest theoretical efficiency (>33%). However, the performance of Sn‐based PSCs lags significantly behind their Pb‐based counterparts. This disparity arises from the susceptibility of Sn2+ to easy oxidation to Sn4+, an energy level mismatch, and fast crystilization. It is widely acknowledged that the oxidation of Sn2+ to Sn4+ results in severe P‐type doping, leading to increased recombination, which is a primary factor contributing to the lower device performance. In this perspective article, we summarized the utilization of metallic Sn in Sn‐based PSCs to facilitate the reduction of Sn4+ back to Sn2+. This approach is preferred due to its effectiveness, simplicity in process, and the absence of introducing additional impurities. Moreover, metallic Sn can serve as a source for synthesizing SnI2 and act as hole transport material through transformation from Sn to SnOx. We hope this article serve as a valuable reference for the ongoing development of Sn‐based materials in PSCs technology.