Inkjet Printing Fabrication Paves Way for Practical Perovskite Solar Cell Production

New approach could offer scalable production of high-efficiency solar cells

WASHINGTON – Researchers from Karlsruhe Institute of Technology have developed a new fabrication technique based on inkjet printing that could enable fast, efficient and scalable production of perovskite solar cells.

Perovskite semiconductors are a very promising material for solar cells because they absorb light and convert it to energy with better efficiency and potentially lower production costs than the silicon used now. However, more work is needed to achieve practical industrial-scale manufacturing of perovskite solar cells.

Helge Eggers, doctoral student in the research group of Dr. Ulrich W. Paetzold from Karlsruhe Institute of Technology, will present the new ink-jet printing approach at The Optical Society (OSA) 2020 Advanced Photonics Congress, an all-virtual meeting held 13-16 July.

Inkjet printing is a scalable and material efficient deposition method for solution-based materials that allows to easily adjust the printing patterns.

“Developing a well-working inkjet printing process for the fabrication of perovskite solar cells could not only enable low-cost mass production, but would also offer to easily modify the printed design based on digital image files opening up the market for individually customized solar cells,” said Eggers.

The research group shows that the new technique can produce solar cells that convert light to power with efficiencies that come close to those achieved with less-scalable fabrication methods. Because their approach could be used to print arbitrary patterns, it could also be useful for printing solar cells onto materials used to turn skylights and building facades into sources of power.

Optimized inkjet printing

The researchers began by using their new approach to create solar cells with an inkjet-printed perovskite absorber layer. Their key achievements were the development of an optimized ink and fabrication process based on vacuum drying. This process allows for a preferable crystallization pattern of the perovskite material with micrometer-large columnar grains. The solar cells exhibited a power conversion efficiency of more than 20 percent, which the authors say is the highest conversion efficiency reported for partially ink-jet printed perovskite solar cells. This result helps close the performance gap with state-of the-art spin-coated perovskite solar cells, which have an efficiency around 25 percent.

They then went one step further by creating perovskite solar cells with inkjet-printed absorber and extraction layers. These solar cells exhibited a power conversion efficiency of more than 17 percent. They also showed that their optimized ink formulation could create millimeter-scale structures by printing detailed portraits of some of the authors.

Although these results are an important step towards the development of scalable perovskite solar cells, there are still key challenges to overcome.

“At the moment we are still processing solar cells on lab scale. Upscaling inkjet-printed perovskite photovoltaics to large areas is an ongoing effort,” said Ulrich W. Paetzold, group leader of the Perovskite Taskforce at Karlsruhe Institute of Technology. “For this, we team up with our industrial partners in the field.”

Inkjet-printed electrodes are under investigation by the group. In addition, the group is still optimizing the quality and reproducibility of the developed inkjet-printing process, since even small changes in homogeneity of the printed film can have a huge influence on the performance of the solar cell.

Conference registration is free. You must register in advance to receive the web link for the conference. All registrants will receive access to the Technical Digest, the live technical sessions and recorded/archived content.

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