Researchers design functionalized interfaces for highly efficient inverted perovskite solar cells

A research team, co-led by scientists from City University of Hong Kong (CityU) and Imperial College London, has developed highly efficient and stable perovskite solar cells.

Among the different types of perovskite solar cells, those with an inverted design configuration have exhibited exceptional stability, making them good candidates to reach the lifetime of commercial silicon solar cells. However, perovskite materials include chemically reactive components, which can easily volatilize and degrade under high temperature and humidity, shortening the solar cells' operational lifetime. Also, there is still a need for strategy to enhance the efficiency of inverted perovskite solar cells up to 25% to rival that of silicon solar cells, while maintaining their stability.

Inspired by the unique properties of a metal-containing material called ferrocenes, Dr. Zhu Zonglong, Assistant Professor in CityU's Department of Chemistry, addressed these challenges with a new approach. In collaboration with Professor Nicholas Long from Imperial College, Dr. Zhu's team added ferrocenes to perovskite solar cells as an interface between the light-absorbing layer and the electron transporting layer, achieving a breakthrough. 'We are the first team to successfully boost inverted perovskite solar cells to a record-high efficiency of 25% and pass the stability test set by the International Electrotechnical Commission (IEC),' said Dr. Zhu.

'The unique properties of ferrocenes can help overcome the problems with perovskite solar cells,' said Professor Long, who is an expert in organometallic chemistry. Ferrocene is a compound with an iron atom 'sandwiched' between two planar carbon rings. Dr. Zhu's team used ferrocene, in which the carbon rings are attached to different organic groups, developed by Professor Long's team. 'These organic groups reduce the reactivity of the perovskite surface, enhancing both efficiency and stability,' Dr. Zhu explained.

Perovskite solar cells are made up of layers of materials with the perovskite layer used for light harvesting. The ferrocene molecules accelerate electron transfer from the perovskite active layer to the electrode in the electricity conversion layer, thus increasing efficiency.

Another merit of these organic groups, according to Dr. Zhu, is that 'the ferrocene-based organometallic compound designed by the joint team firmly anchors the ion on the perovskite surface via a strong chemical bond, reducing the solar cells' sensitivity to the external environment and delaying the device degradation process.'

In the experiment, the team found that these newly invented solar cells can run under continuous illumination for more than 1,500 hours and still maintain more than 98% of their initial efficiency. The devices also passed the international standard for mature photovoltaics, exhibiting superior stability in a hot and humid environment (85 degrees Celsius and 85% humidity).

'The most important part of this work is that we successfully fabricated highly efficient perovskite solar cells while providing promising stability. The reliable results mean that the commercialization of perovskites is on its way,' said Dr. Zhu.

The collaboration team patented their design. 'We aim to scale up the production of perovskite solar cells using this novel molecule and facile method, contributing to the global 'zero-carbon' sustainability goal,' concluded Dr. Zhu.