腦瞳憫

12 February 2025

In a study published in Nature, researchers at 腦瞳憫 have developed a method to recycle all parts of a solar cell repeatedly without environmentally hazardous solvents. The recycled solar cell has the same efficiency as the original one. The solar cell is made of perovskite and the main solvent is water.

A beaker filled with water where a small solar cell is dissolved.
One of the most promising technologies for next-generation solar cells involves perovskite. Now researchers at 腦瞳憫 have developed a method to recycle all parts of a perovskite solar cell repeatedly using water as the main solvent. Photographer: Thor Balkhed

Electricity use is expected to increase drastically in the coming years with the development of AI and the transition to electrified transport, among other things. In order for the change to not drive climate change, different sustainable energy sources need to work together.

Solar energy has long been considered to have great potential and solar panels based on silicon have been on the market for over 30 years. But first-generation silicon solar panels are at the end of their life cycle, which has created an unexpected problem.

Three persons walking in a staircase.
Professor Feng Gao together with postdocs Xun Xiao and Niansheng Xu at the Department of physics, chemistry and biology. Photographer: Thor Balkhed

There is currently no efficient technology to deal with the waste of silicon panels. Thats why old solar panels end up in the landfill. Huge mountains of electronic waste that you cant do anything with, says Xun Xiao, postdoc at the Department of Physics, Chemistry and Biology (IFM) at Link繹ping University (LiU).

Feng Gao, professor of optoelectronics at the same department, adds:

We need to take recycling into consideration when developing emerging solar cell technologies. If we dont know how to recycle them, maybe we shouldnt put them on the market at all.

Avoid another landfill

One of the most promising technologies for next-generation solar cells involves perovskite. They are not only relatively inexpensive and easy to manufacture but also lightweight, flexible and transparent. Thanks to these properties, perovskite solar cells can be placed on many different surfaces, even on windows. Also, they can convert up to 25 per cent of the solar energy into electricity, which can be comparable to todays silicon solar cells.

Researcher in the lab under a fan hood.
Postdoc Xun Xiao in the lab. Photographer: Thor Balkhed

There are many companies that want to get perovskite solar cells on the market right now, but wed like to avoid another landfill. In this project, weve developed a method where all parts can be reused in a new perovskite solar cell without compromising performance in the new one, says Niansheng Xu, postdoc at LiU.

However, given that perovskite solar cells currently have a shorter life span than silicon solar cells it is important that perovskite solar cell recycling is efficient and environmentally friendly. Perovskite solar cells also contain a small amount of lead that is necessary for high efficiency, but this also places great demands on a functioning recycling process.

In addition, there are also legal requirements in large parts of the world for producers to collect and recycle end-of-life solar cells in a sustainable way.

Water as the solvent

There are already methods for dismantling perovskite solar cells. This mostly involves using a substance called dimethylformamide, a common ingredient in paint solvents. It is toxic, environmentally hazardous and potentially carcinogenic. What the Link繹ping researchers have now done is to instead develop a technology where water can be used as a solvent in dismantling the degraded perovskites. And more importantly, high-quality perovskites can be recycled from the water solution.

Two researchers in a lab.
Niansheng Xu and Xun Xiao are the main authors of the paper published in the journal Nature. Photographer: Thor Balkhed

We can recycle everything covering glasses, electrodes, perovskite layers and also the charge transport layer. says Xun Xiao.

The next step for the researchers is to develop the method for larger scale use in an industrial process. In the long term, they believe that perovskite solar cells can play an important role in providing the energy when surrounding infrastructure and supply chains are in place.

The study was funded by the Knut and Alice Wallenberg Foundation, the Wallenberg Initiative Materials Science for Sustainability, The Swedish Energy Agency and through the Swedish Governments strategic area in advanced functional materials, AFM, at Link繹ping University. Researchers Xun Xiao, Niansheng Xu and Feng Gao have applied for patents on the technology described above.

Article: , Xun Xiao, Niansheng Xu, Xueyu Tian, Tiankai Zhang, Bingzheng Wang, Xiaoming Wang, Yeming Xian, Chunyuan Lu, Xiangyu Ou, Yanfa Yan, Licheng Sun, Fengqi You, Feng Gao; Nature (2025) Published online 12 February 2025. Doi: 10.1038/s41586-024-08408-7

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