Affiliation:
1. Department of Materials Science and Engineering Stanford University Stanford CA 94035 USA
Abstract
Perovskite (PVSK) solar cells offer significant benefits over conventional silicon cells including low‐cost solution processibility, minimal materials usage related to strong photon absorption in thin‐film cell architectures, and a tunable bandgap. However, PVSK films are mechanically fragile, and fracture of PVSK layers and adjacent interfaces are a significant concern during fabrication, encapsulation, and operation. Herein, a thin‐film mechanics fracture analysis tailored for p–i–n and n–i–p PVSK solar cells on both soda lime glass and polyimide substrates fabricated with three PVSK crystallization methods is presented. The role of thermal processing of each cell layer is explored to determine the maximum allowable temperature below which fracture is inhibited. In the analysis, the mechanics basis for processing and materials selection guidelines for preventing fracture in PVSK solar cells is provided.
Funder
Office of Energy Efficiency and Renewable Energy
National Science Foundation Graduate Research Fellowship Program