How robots can help find the solar energy of the future

How robots can help find the solar energy of the future

Finding the best material to make solar cells is a colossal task, but a research team at Osaka University has been using robotic systems and AI to make the search faster and more efficient

Oct 25, 2023

Solar energy is one of the most promising ways to power the world of the future. However, creating more efficient solar cells requires finding new and better materials. Now, in a study recently published in JACS Au, researchers at Osaka University have unveiled a solution: a system that automates key experimental and analytical processes to speed up research on solar materials considerably.

There’s more to solar cells than just silicon, and other potential materials may be even more effective. To be used on a large scale, though, these materials need to meet a few important requirements – they must be highly efficient, made from common chemical elements, and have low toxicity. So far, not many candidates have the potential to check all three of these boxes. Furthermore, studies into new materials are currently done by hand and are costly and time-consuming.

To speed up the discovery of these materials, the researchers created a unique robotic measurement system that’s able to perform photoabsorption spectroscopy, optical microscopy, and time-resolved microwave conductivity analyses. They then used the robot to evaluate 576 different thin-film semiconductor samples.

"Current solar cells are made of inorganic semiconductors containing silicon and gallium, but next-generation solar cells need to reduce both cost and weight," explains lead author Chisato Nishikawa. "Safety is also a concern; perovskite solar cells are efficient enough to rival silicon solar cells, but they contain toxic lead."

The samples tested in this study were all made from a varying blend of cesium, bismuth, tin, and iodine. They were also annealed at different temperatures and treated with different organic salt additives. To thoroughly characterize the material properties as well as automate the experimental process, the researchers also examined the data using artificial intelligence – specifically, machine learning.

"In recent years, machine learning has been very helpful in better understanding the properties of materials. These studies require vast amounts of experimental data, and combining automated experiments with machine-learning techniques is an ideal solution," says senior author Akinori Saeki.

The authors hope to automate even more of the process in the future, making it easier to examine completely new materials. As Nishikawa notes, "This method is ideal for exploring areas where there's no existing data."

The research team have had promising results with their robotic system so far. The measurement process is both fully automated and highly accurate, allowing work to be completed in one-sixth of the usual time needed.

The automated system makes the task of finding efficient and non-toxic solar materials considerably easier. With the help of robots and AI, the future of solar energy may be closer than we realize.

20231025_2_fig_1.jpg

Fig. 1

Picture of an operating robot performing a microwave conductivity measurement.

Credit: Akinori Saeki

20231025_2_fig_2.png

Fig. 2

(a) Illustration of an automated measurement system. (b) Examples of photoabsorption (PA), photoluminescence (PL), microwave conductivity, and optical microscope image data.

Credit: Akinori Saeki

20231025_2_fig_3.png

Fig. 3

(a) Pictures of ~500 film samples on quartz substrates subjected to the automated measurements. (b) Bar chart of power conversion efficiencies of control and newly processed Cs-Bi-Sb-I solar cells.

Credit: Akinori Saeki

The article, "Exploration of Solution-Processed Bi/Sb Solar Cells by Automated Robotic Experiments Equipped with Microwave Conductivity," will be published in JACS Au at DOI: https://doi.org/10.1021/jacsau.3c00519.


Related Links

SDGs

  • 07 Affordable and Clean Energy
  • 09 Industry, Innocation and Infrastructure
  • 13 Climate Action