Engineers eliminate surface concavities to produce more efficient and stable perovskite solar cells

A research team from the School of Engineering of the Hong Kong University of Science and Technology (HKUST) has shown the existence of surface concavities on individual crystal grains, which are the fundamental building blocks of perovskite thin films, while revealing their significant effects on film properties and reliability.

Based on this fundamental scientific discovery, the team has pioneered a new way of making perovskite solar cells more efficient and stable via a chemo-elimination of these grain surface concavities.

Perovskite solar cells are a stellar solar-cell technology that has demonstrated potential to replace existing silicon solar cells in a wide range of application scenarios, such as grid electricity, portable power, and space photovoltaics.

They not only attain higher power conversion efficiencies (PCEs) than commercial silicon cells, but also offer advantages in terms of low material costs, sustainable manufacturing, and high versatility in transparency and colors.

However, the long-term stability of perovskite devices under light, humidity, and thermomechanical conditions remains a hurdle in the commercialization of this promising solar technology.

To address this issue, Prof. Zhou Yuanyuan, Associate Professor of the Department of Chemical and Biological Engineering at HKUST, and his research group have conducted research from the unique perspective of the materials' microstructure. They discovered a proliferation of surface concavities at the crystalline grains of the perovskite material.

These concavities are shown to break the structural continuity at the perovskite film interface, serving as a hidden microstructure factor limiting the efficiency and stability of perovskite cells.

Then, the team took an innovative step to remove the grain surface concavities by using a surfactant molecule, tridecafluorohexane-1-sulfonic acid potassium, to manipulate the strain evolution and ion diffusion during the formation of perovskite films.

Accordingly, their final perovskite cells demonstrated obvious improvements in efficiency retention under standardized thermal cycling, damp heat, and maximum-power-point tracking tests.

The article, titled "Elimination of grain surface concavities for improved perovskite thin-film interfaces," has now been published in Nature Energy. The work was a collaborative effort between Hong Kong Baptist University and Yale University.

"Structure and geometry of individual crystalline grains are the origin of the performance of perovskite semiconductors and solar cells. By unveiling the grain surface concavities, understanding their effects, and leveraging chemical engineering to tailor their geometry, we are pioneering a new way of making perovskite solar cells with efficiency and stability toward their limits," said Prof. Zhou, the corresponding author of this work.

"We were very intrigued by the surface concavities of perovskite grains when we were using atomic force microscopy to examine the structural details of perovskite films. These concavities are usually buried underneath the film bottom and easily be overlooked," he added.

"Microstructure is of vital importance for perovskite solar cells and other optoelectronic devices, and can be more complex than conventional materials owing to the hybrid organic-inorganic characteristics of perovskite materials.

"Under Prof. Zhou's guidance, we are able to develop various novel characterization and data science approaches to gain insights into perovskite microstructure," said Zhang Yalan, a Ph.D. student in Prof. Zhou's research group and a co-author of this work.