Interdisciplinary science research for enhancing sustainability through solar cells
Professor Zhu Zonglong (left) and Dr Gao Danpeng of the Department of Chemistry of City University of Hong Kong hold their innovative solar cells.
Professor Zhu (left) and Dr Gao of the Department of Chemistry of CityUHK hold their innovative solar cells.

Drawing on an array of interdisciplinary science research and knowledge, a new fabrication technique for substantially enhancing the prospects of commercialising perovskite solar cells through improved stability, reliability, efficiency and affordability is underway at City University of Hong Kong (CityUHK).

Published in Science, the research is significant because the simple device structure that the CityUHK team has built can facilitate future industrial production and enhance confidence in the commercialisation of perovskite solar cells.

The project exemplifies the interdisciplinary science research that has propelled CityUHK to #25 in the world, and #2 in Hong Kong, out of the 749 institutions that participated in the THE Interdisciplinary Science Rankings 2025, with insights from materials innovation, interfacial engineering, renewable energy, and nanotechnology.

Two innovations

In broad terms, the CityUHK team is working on a new type of solar cell that can turn sunlight into electricity more efficiently and last longer than current solar cells.

The CityUHK innovation for solar cells (pictured right) can lead to improved stability, reliability, efficiency and affordability when compared to the “traditional device structure” (pictured left).
The CityUHK innovation for solar cells (pictured right) can lead to improved stability, reliability, efficiency and affordability when compared to the “traditional device structure” (pictured left).

The team has developed two innovations for creating the structure of the solar cells. The first innovation is the integration of the hole-selective materials and the perovskite layers, which simplifies the manufacturing process.

The second is that the operational stability of the device is greatly enhanced by using the inorganic electron transport layer, tin oxide, which has excellent thermal stability, to replace traditional organic materials such as fullerene and BCP.

“The device structure reported in this study represents the most simplified architecture in the current field of perovskite solar cells, offering significant advantages for industrialisation,” said Dr Gao Danpeng, co-author of the Science paper and a Postdoc at CityUHK.

Specifically, Dr Gao explained that this solution does not require a traditional organic transfer layer, effectively reducing the material cost in the manufacturing process while greatly simplifying the production steps.

Cost-effective and sustainable

The study has produced some promising data. According to Professor Zhu, the team has achieved power conversion efficiencies exceeding 25% by optimising oxygen vacancy defects within the tin oxide layer while retaining over 95% efficiency after 2,000 hours of continuous operation under rigorous test conditions.

The simple device structure that the CityUHK team has built can facilitate future industrial production and enhance confidence in the commercialisation of perovskite solar cells.
The simple device structure that the CityUHK team has built can facilitate future industrial production and enhance confidence in the commercialisation of perovskite solar cells.

This performance surpasses the stability of traditional perovskite solar cells, meeting several industry benchmarks for longevity. The results pave the way for more reliable and efficient solar cells, simplifying manufacturing processes and making producing solar cells at scale more cost-effective.

Researchers in materials science, renewable energy technology, and solar cell manufacturing companies are likely to be interested in this research because it can revolutionise the production and long-term stability of perovskite solar cells. Additionally, energy consumers and environmental organisations will see the benefits of more efficient, durable, and easier-to-manufacture solar cells.

Not only that, policymakers focused on environmental protection will find this research noteworthy as it promotes broader applications of renewable energy, reducing reliance on fossil fuels and protecting the environment and climate.

Scaling up

The team includes (from left) Francesco Vanin, PhD student of the Department of Chemistry; Dr Liu Qi, Research Associate of the Department of Materials Science and Engineering; Professor Zhu; Dr Li Bo, Research Associate of the Department of Chemistry; Professor Zeng Xiaocheng, Head of the Department of Materials Science and Engineering; and Dr Gao.
The team includes (from left) Francesco Vanin, PhD student of the Department of Chemistry; Dr Liu Qi, Postdoc of the Department of Materials Science and Engineering; Professor Zhu; Dr Li Bo, Research Associate of the Department of Chemistry; Professor Zeng Xiaocheng, Head of the Department of Materials Science and Engineering; and Dr Gao.

This development in solar cell research could profoundly impact global energy markets and help accelerate the shift towards renewable energy sources, the CityUHK teams said, while the next phase of the study will focus on applying this innovative structure to larger perovskite solar modules, aiming further to enhance the efficiency and scalability of this technology.

This research was conducted in collaboration with teams from the National Renewable Energy Laboratory and Imperial College London, underscoring the global effort to develop sustainable energy solutions.

“With the potential to be implemented in solar energy systems within the next 5 years, this research is a critical step towards achieving more sustainable and environmentally friendly energy production globally,” Professor Zhu added.

The Science paper is titled "Long-term stability in perovskite solar cells through atomic layer deposition of tin oxide."