Understanding Grain-Morphology-Dependent Grain Degradation for Improved Stability

Abstract

The stability of perovskite solar cells has shown huge variation with respect to film process and film morphology; however, the underlining mechanism for the morphology-dependent perovskite film degradation has remained elusive. The research team will investigate the influence of film morphology, such as grain size, grain orientation, facet, surface terminating group, and ferroelastic domains, on the intrinsic stability of polycrystalline perovsktie films to moisture, temperature, light, and mechanical bending. The perovskite grains will be formed by six different methods from the lab process to the scalable process. We will combine a set of material structure, optical, and electrical characterizations to reveal the relationship between material process, morphology, and performance, particularly on the fluence of defects in film degradation process by monitoring its influence on ion migration, moisture permeation, film thermal decomposition, and shape change. The study results will guide the design of film and highly stable devices without compromising efficiency. In addition, the research team will explore techniques to enhance the intrinsic and extrinsic stability of perovskite grains with enlarged grain size, defect remedy, and grain level encapsuluation. This project leverages the research team’s extensive experience in grain structure control by requiring a variety of different methods and characterizations and by encouraging preliminary results on high efficiency and long lifetime devices.

Document Details

Document Type

DoD Grant Award

Publication Date

Jan 04, 2017

Source ID

N000141712163

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