Title: Low-Cost Scaffold-Reinforced Perovskite Solar Modules with Integrated Light Management

Perovskite solar cells are a promising new solar technology because they are highly efficient and cheaper to manufacture compared to silicon solar cells. However, perovskites suffer from mechanical and thermal fragility, important factors limiting device lifetimes, which leads to problems in making reliable solar cells. In our recent work, we showed how to make perovskite solar cells that look like the eye of a fly by subdividing a solar cell into thousands of microcells that are surrounded by a honeycomb-shaped reinforcing scaffold. This discovery was a new architecture called a compound solar cell (CSC). The perovskite is effectively shielded from mechanical forces by the scaffold and leads to robust solar cells that are no longer fragile. This was a promising advancement, but the drawback of the scaffold structure is that the scaffold absorbs light from the solar cell and leads to a reduced efficiency. In this project, we address this reduced efficiency by integrating concentrating lens arrays into CSCs to focus any incident light away from the scaffolds. Perovskite is deposited into the microcells between these scaffolds, and upon sunlight exposure, the lenses concentrate light into the microcells and away from the insulating scaffolds, resulting in significantly improved efficiencies. The lenses redirect over 90% of the light that otherwise would have been incident on the scaffolds into the microcells leading to a corresponding 90% recovery of efficiency. Furthermore, the lenses show passive light tracking capabilities, meaning as the angle of incident light changes (simulating how the sunlight moves across the sky during the course of the day), a majority of the light is still focused into the perovskite microcells. The improved efficiency and passive tracking capabilities suggest that lens-integrated CSCs are a potential pathway to high-performance, robust, commercially viable perovskite solar cells.