Particle irradiation can change the structure and properties of semiconductor materials, which can be either beneficial or harmful, depending on the situation. For example, irradiation, in particular with dopant species, can improve certain properties in silicon-based power devices, but in high-radiation environments, energetic particles can damage materials used in satellites or other critical technologies. Understanding how radiation affects these materials helps improve their performance and reliability.
The MUST project aims to improve how we predict the effects of radiation on semiconductors, with focus on wide band gap materials, which are strong candidates for next-generation devices. The main goal is to merge advanced physics models to make quantitative predictions about how these materials will behave in extreme environments, such as space or high-radiation areas. We do this by using powerful computers for advanced calculations, combined with cutting-edge multi-scale modeling techniques to accurately predict how radiation will affect these materials at the atomic level.
The project aims to push beyond current limits in radiation damage simulations, reaching a level of precision not yet achieved, to be able to predict the effects of irradiation based on a bottom-up approach from basic physics, rather than relying on empirical models. The methods developed and validated in the MUST project will be extendable to other compound semiconductor materials. This will significantly improve our ability to design radiation-resistant semiconductor devices, which are essential for technologies like satellite communications, space exploration, and secure global communications. In essence, this research will help design materials that can withstand extreme radiation conditions, opening up new possibilities for electronics in space and other high-risk environments, while making the development of these materials more cost-effective and efficient.