Affiliation:
1. Materials Science Center National Renewable Energy Laboratory Golden CO 80401 USA
2. Department of Chemistry Colorado School of Mines Golden CO 80401 USA
3. Chemistry and Nanoscience Center National Renewable Energy Laboratory Golden CO 80401 USA
4. Department of Physics University of Colorado Boulder CO 80309 USA
5. Renewable and Sustainable Energy Institute University of Colorado Boulder CO 80309 USA
Abstract
Metal halide perovskite photovoltaic performance required for commercial technology encompasses both efficiency and stability. Advances in both these parameters have recently been reported; however, these strategies are often difficult to directly compare due to differences in perovskite composition, device architecture, fabrication methods, and accelerated stressors applied in stability tests. In particular, it is found that there is a distinct lack of elevated temperature, operational (light and bias) stability data. Furthermore, significant testing is required to understand the interactions when combinations are used (e.g., additives used with posttreatments). Herein, individual and combined additive, posttreatment, and contact layer strategies from recent literature reports under standardized operational stability tests of p–i–n CsMAFA perovskites at 70 °C are evaluated. Through analysis of over 1000 devices, it is concluded that the hole‐transport layer (HTL) is the most significant component impacting elevated temperature operational stability. This analysis motivates future development of high‐performance HTLs.
Funder
Solar Energy Technologies Office
Subject
Electrical and Electronic Engineering,Energy Engineering and Power Technology,Atomic and Molecular Physics, and Optics,Electronic, Optical and Magnetic Materials
Cited by
3 articles.
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