Electrochromic smart windows can reduce the energy consumption of buildings by managing the light and heat transmission. However, they need external power to work, raising the installation cost and compromising the aesthetics of the buildings. Self‐powered smart windows without external power sources have great potential in practical applications. Transparent solar cells can be integrated with smart windows and serve as their power sources. High optical transmittance, good color neutrality, and high power conversion efficiency (PCE) are required for the transparent solar cells to meet the optical and power requirements of self‐powered smart windows. Herein, an efficient MAPbCl3‐based transparent perovskite solar cell (TPSC) using a solvent‐assisted two‐step approach is developed. The transparency and color‐neutrality of the TPSCs are optimized through delicately selecting and pairing the charge transport layers and transparent electrodes. The TPSCs achieve a PCE up to 1.06% and average visible transmittance up to 72%. Self‐powered smart windows powered by the TPSCs show fast and reversible modulation of visible light from 55% to 5% without external power input. This work demonstrates the prospect of deploying TPSCs in a self‐powered smart window for energy saving and sustainable buildings.
Antimony selenide (Sb2Se3) is regarded as an excellent photovoltaic absorber material due to its suitable bandgap, large light absorption coefficient, abundant raw material reserves, and environmental friendliness. However, the commonly used rapid thermal evaporation strategy for deposition of Sb2Se3 films results in low film quality, which is undesirable from the perspective of photovoltaic performance. Herein, we fabricate highly efficient and stable Sb2Se3 solar cells via a close-space sublimation (CSS) process, which allows separate control of the source and substrate temperatures, leading to high-quality thin films and better solar cell performance. Four growth patterns of Sb2Se3 thin films are optimized by controlling the source temperature of CSS. It is found that the Sb2Se3 thin film prepared at 475 °C has the best crystallinity, smoothest surface, and best density. Moreover, solar cells based on ZnO/Sb2Se3 thin films can achieve maximum efficiency with VOC of 0.312 V, JSC of 27.91 mA/cm2, fill fact of 41.35%, and power conversion efficiency of 3.61%. The performance of the devices was not adversely affected by the air environment, and thus, they were shown to exhibit appropriate stability.
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