Solar cells using a halide perovskite with an organic cation such as methylammonium and/or formamidinium have attracted considerable attention because of their excellent photovoltaic performance. Over a period of just a few years, their power conversion efficiency has rocketed to greater than 22%.
However, PSCs face challenges to commercialization. Specifically, they have the following needs that must be addressed for the eventual success of this promising technology: 1) long-term stability, 2) a manufacturing method that can produce reproducible, hysteresis-free, high-performance devices, and 3) reliable device characterization.
Park initiated this joint effort to provide solutions to these needs, and the authors proposed a strategy-to move toward stable commercial PSCs-that includes the following:
• Developing a reproducible manufacturing method that takes into account managing grain boundaries and interfacial charge transport.
• Using electroluminescence as an effective metric or tool for evaluating PSC quality.
• Realizing the importance of the design of device structures with interface engineering to yield performance that is stable and hysteresis-free.
• Recovering and utilizing the lead in PSCs to address environmental concerns.
• Ensuring the advance of practical applications through reliable device characterization.
Details of the strategy are found in the paper, “Towards Stable and Commercially Available Perovskite Solar Cells,” published in Nature Energy. The authors are Nam-Gyu Park (Sungkyunkwan University, Korea), Michael Grätzel (Ecole Polytechnique Federale de Lausanne, Switzerland), Tsutomu Miyasaka (Toin University of Yokohama, Japan), and Kai Zhu and Keith Emery from NREL.