Solar cells, devices that convert sunlight into electricity, are helping to reduce greenhouse gas emissions worldwide, promoting a shift toward renewable energy sources. Most solar cells used today are based on silicon, yet researchers have recently been exploring the potential of other photovoltaic materials, particularly perovskites.

Perovskites are a class of photovoltaic materials with strong light absorption. In practical devices, perovskite thin films are typically polycrystalline, meaning they consist of many small crystalline grains. As perovskites absorb sunlight so efficiently, a film thinner than ~1 μm can capture most of the incident solar radiation, whereas conventional crystalline silicon usually requires hundreds of micrometers of active material.

This combination of strong absorption and ultrathin active layers makes perovskite thin-film solar cells particularly well suited for lightweight, flexible, high-efficiency photovoltaic devices. Despite these many advantages, perovskites still face inherent challenges, such as achieving true mechanical flexibility, operational stability, and maintaining high efficiency at large areas simultaneously.

Solar cells, devices that can convert sunlight into electricity, are now widely used in many countries worldwide. Over the past few years, energy engineers have been exploring alternative designs that could further boost these devices’ power conversion efficiencies (PCEs) and ensure that they continue operating reliably over time.

Researchers at Soochow University, Zhejiang Jinko Solar Co. Ltd. and other institutes introduced a new bifacial solar cell design that could overcome some of the limitations of a recently introduced type of solar cell that leverage components known as tunnel oxide passivating contacts (TOPCon). Their design, outlined in a paper published in Nature Energy, combines TOPCon structures with perovskites, a class of materials with a unique crystal structure that efficiently absorbs light.

“Our work is rooted in a fundamental limitation of current TOPCon solar cells,” Kun Gao and Prof. Xinbo Yang, first author and co-senior author of the paper, respectively, told Tech Xplore. “In industrial TOPCon devices, a boron-diffused p+ emitter is still used on the front side, which introduces significant recombination losses and limits further efficiency improvements. A natural strategy is to replace this emitter with localized TOPCon contact.”