Zhu Xueliang, Xiong Wenqi, Hu Chong, Mo Kangwei, Yang Man, Li Yanyan, Li Ruiming, Shen Chen, Liu Yong, Liu Xiaoze, Wang Sheng, Lin Qianqian, Yuan Shengjun, Liu Zhengyou, Wang Zhiping
School of Physics and Technology, Hubei Luojia Laboratory, Key Lab of Artificial Micro- and Nano-Structures of Ministry of Education, School of Microelectronics Wuhan University, Wuhan, 430072, China.
Wuhan Institute of Quantum Technology, Wuhan, 430206, China.
Adv Mater. 2024 Apr;36(15):e2309487. doi: 10.1002/adma.202309487. Epub 2024 Jan 11.
Electronic band structure engineering of metal-halide perovskites (MHP) lies at the core of fundamental materials research and photovoltaic applications. However, reconfiguring the band structures in MHP for optimized electronic properties remains challenging. This article reports a generic strategy for constructing near-edge states to improve carrier properties, leading to enhanced device performances. The near-edge states are designed around the valence band edge using theoretical prediction and constructed through tailored material engineering. These states are experimentally revealed with activation energies of around 23 milli-electron volts by temperature-dependent time-resolved spectroscopy. Such small activation energies enable prolonged carrier lifetime with efficient carrier transition dynamics and low non-radiative recombination losses, as corroborated by the millisecond lifetimes of microwave conductivity. By constructing near-edge states in positive-intrinsic-negative inverted cells, a champion efficiency of 25.4% (25.0% certified) for a 0.07-cm cell and 23.6% (22.7% certified) for a 1-cm cell is achieved. The most stable encapsulated cell retains 90% of its initial efficiency after 1100 h of maximum power point tracking under one sun illumination (100 mW cm) at 65 °C in ambient air.
金属卤化物钙钛矿(MHP)的电子能带结构工程是基础材料研究和光伏应用的核心。然而,重新配置MHP中的能带结构以优化电子性能仍然具有挑战性。本文报道了一种构建近边态以改善载流子特性的通用策略,从而提高器件性能。利用理论预测在价带边缘附近设计近边态,并通过定制的材料工程构建这些态。通过温度相关的时间分辨光谱实验揭示了这些态的激活能约为23毫电子伏特。如此小的激活能使得载流子寿命延长,具有高效的载流子跃迁动力学和低非辐射复合损失,微波电导率的毫秒级寿命证实了这一点。通过在正本征负倒置电池中构建近边态,0.07平方厘米的电池实现了25.4%(认证为25.0%)的冠军效率,1平方厘米的电池实现了23.6%(认证为22.7%)的冠军效率。在环境空气中65℃下一个太阳光照(100毫瓦/平方厘米)下进行1100小时最大功率点跟踪后,最稳定的封装电池保留了其初始效率的90%。
