High-intensity synchrotron radiation sources make on-site experiments possible and can handle data exceeding terabytes. The new technology has improved speed and resolution, with speed increasing by one to two orders of magnitude and resolution by one order of magnitude compared to traditional methods, driving scientific research forward. Combined with automated sample exchange, alignment systems, and AI-driven automated data processing, this technology becomes a powerful analytical tool.

High-intensity synchrotron radiation sources make in-situ experiments possible and can handle data exceeding terabytes. The new technology has increased speed and resolution, with speed improving by one to two orders of magnitude and resolution by one order of magnitude compared to traditional methods, driving scientific research forward. Additionally, with automated sample exchange, alignment systems, and AI-driven automated data processing, this technology becomes a powerful analytical tool.

In energy materials, it can observe the internal structure and defects of lithium battery materials. In environmental science, it is used to study the distribution of soil and pollutants. In biotechnology, it can analyze biological tissues and develop medical devices. In paleontology, it detects fossil structures to reveal biological evolution. In the 3D printing of novel materials, it examines internal structures and defects, enhancing product quality.