New Study Reveals Modular Clear Silicon Solar Cells

Abstract

Transparent solar cells (TSCs) hold substantial potential as continuous energy generators, enabling their use in situations where conventional devices may not be feasible. However, research aimed at modularizing TSCs for the purpose of regulating the overall voltage and current they produce, a critical step toward practical application, is still in its nascent stages. In this study, we explored a custom-designed, all-back-contact (ABC) configuration, which situates all electrical contacts on the rear side, to create glass-like transparent crystalline silicon (c-Si) solar cells and seamless modules. The ABC design not only demonstrates high power conversion efficiency (PCE) in solar cells but also ensures unobstructed visibility through transparent solar modules. Notably, ABC-transparent c-Si solar cells achieved a peak PCE of 15.8% while maintaining an average visible transmittance of 20%. Through seamlessly interconnecting the unit cells, the output voltage and power were systematically tuned from 0.64 V and 15.8 mW (for a 1 cm2-sized unit cell) to 10.0 V and 235 mW (for a 16 cm2-sized module). Furthermore, we successfully demonstrated the photocharging of a smartphone using a transparent ABC solar module.

A technology that can directly charge a battery from a smartphone screen has emerged. A research team, affiliated with UNIST has unveiled a method of supplying energy directly from glass of buildings, cars, and mobile devices through transparent solar cells.

Professor Kwanyong Seo and his research team in the School of Energy and Chemical Engineering at UNIST introduced a new type of transparent solar cell and module with high efficiency while maintaining glass-like colorless and transparent properties. It has secured colorless and transparentness by introducing an 'all-back-contact' design that places all the components of the solar cell on the back. It has achieved high efficiency and aesthetics that transparent solar cells must have at the same time.

The research team developed Seamless Modularization technology that eliminates gaps between devices without using metal wires. In the existing modularization method, the gap between devices and opaque metal wires have solved the problem of damaging the aesthetics of transparent solar cells.

The newly developed 16 cm²-sized transparent solar cell module has high efficiency ranging from 20% to 14.7% in transmittance while maintaining aesthetics similar to that of a single device. It has also succeeded in charging a smartphone using natural sunlight. It also proved the possibility that a screen of a small mobile device can be used as an energy source.

"This study fundamentally solved the aesthetic problem of the existing solar cell modularization method through the design of the new device structure," said researcher Jeonghwan Park and Research Assistant Professor Kangmin Lee. "It presented the possibility that transparent silicon solar cells can be used in various industries such as small devices as well as buildings and automobile glass."

Professor Seo said, "We have opened a new path for modularization research, which is essential for commercialization of transparent silicon solar cells," and added, "We plan to continue further research so that transparent solar cells can become a key technology in the eco-friendly future energy industry."

The research was published in the international journal Proceedings of the National Academy of Sciences (PNAS) on August 7, 2024. The research was carried out with the support of the Korea Institute of Energy Technology Evaluation and Planning (KETEP) and the equipment and facilities of the UNIST Central Research Facilities (UCRF).

Journal Reference

Jeonghwan Park, Kangmin Lee, Jungtaek Lee, et al., "All-back-contact neutral-colored transparent crystalline silicon solar cells enabling seamless modularization," PNAS, (2024).

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