Constructing Ultra-Shallow Near-Edge States for Efficient and Stable Perovskite Solar Cells

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-cm2 cell and 23.6% (22.7% certified) for a 1-cm2 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-2) at 65 degrees C in ambient air. Efficient doping of hybrid perovskites holds the potential to further advance solar cell efficiency. This study presents a generic strategy for perovskite doping by constructing ultra-shallow near-edge states. These states can effectively prolong electron-hole recombination through efficient trap and de-trap processes, resulting in over 25% efficiency in inverted perovskite solar cells with superior long-term operational stability.image