Quantum collision theory for astrophysics, fusion energy and hadron therapy. The project intends to investigate collision processes involving charged particles interacting with complex atoms and molecules. Although the theory of electron, positron and ion collisions with simple atoms and molecules has advanced in recent years, the corresponding computational modelling is difficult due to the mix of the countably and uncountably infinite spectrum of the target, the long-range Coulomb potential, a ....Quantum collision theory for astrophysics, fusion energy and hadron therapy. The project intends to investigate collision processes involving charged particles interacting with complex atoms and molecules. Although the theory of electron, positron and ion collisions with simple atoms and molecules has advanced in recent years, the corresponding computational modelling is difficult due to the mix of the countably and uncountably infinite spectrum of the target, the long-range Coulomb potential, and the multicentre nature of the target and the rearrangement processes. These difficulties could be overcome using a convergent close-coupling method. This project plans to apply the method to complex quantum collision systems in diverse applications of current interest such as fusion energy, lighting, astrophysics, and cancer imaging and therapy.Read moreRead less
Quantum collision theory for astrophysics, fusion energy and hadron therapy. The project intends to investigate collision processes involving charged particles interacting with complex atoms and molecules. Although the theory of electron, positron and ion collisions with simple atoms and molecules has advanced in recent years, the corresponding computational modelling is difficult due to the mix of the countably and uncountably infinite spectrum of the target, the long-range Coulomb potential, a ....Quantum collision theory for astrophysics, fusion energy and hadron therapy. The project intends to investigate collision processes involving charged particles interacting with complex atoms and molecules. Although the theory of electron, positron and ion collisions with simple atoms and molecules has advanced in recent years, the corresponding computational modelling is difficult due to the mix of the countably and uncountably infinite spectrum of the target, the long-range Coulomb potential, and the multicentre nature of the target and the rearrangement processes. These difficulties could be overcome using a convergent close-coupling method. This project plans to apply the method to complex quantum collision systems in diverse applications of current interest such as fusion energy, lighting, astrophysics, and cancer imaging and therapy.Read moreRead less