Self-Powered X-Ray Detector Could Revolutionize Imaging

Also, as the perovskite detectors are photocurrent devices, they do not require an outside power source to operate; instead, they work by generating substantial x-ray photon–induced open-circuit voltages in response to bombardment by X-ray beams.

The Perovskite films can be deposited on surfaces by spraying solutions that cure and leave thin layers of the material behind. As a result, the thin-layer detectors will be much easier and cheaper to produce than silicon-based detectors, which require high-temperature metal deposition under strict vacuum conditions. The lower-energy, increased-resolution detectors could also revolutionize security scanners and imaging in high-energy research facilities, for example those that use synchrotron light sources. The study was published on April 10, 2020, in Science Advances.

“The perovskite material at the heart of our detector prototype can be produced with low-cost fabrication techniques. Potentially, we could use ink-jet types of systems to print large scale detectors,” said lead author Hsinhan (Dave) Tsai, PhD, of the LANL department of materials physics and applications. “The result is a cost-effective, highly sensitive, and self-powered detector that could radically improve existing X-ray detectors, and potentially lead to a host of unforeseen applications.”

Perovskite, named after Russian mineralogist Lev Perovski (1792–1856), is a mineral that was discovered in the Ural Mountains by Gustav Rose in 1839. It is composed mainly of calcium titanate, and is rich in heavy elements, such as lead and iodine. As a result, X-rays that easily pass through silicon undetected are more readily absorbed, and detected, in perovskite.

Related Links:
Los Alamos National Laboratory
Argonne National Laboratory