Nonadiabatic transition is a highly multidisciplinary concept and phenomenon, constituting a fundamental mechanism of state and phase changes in various dynamical processes of physics, chemistry and biology, such as molecular dynamics, energy relaxation, chemical reaction, and electron and proton transfer. Control of molecular processes by laser fields is also an example of time-dependent nonadiabatic transition. In this new edition, the original chapters are updated to facilitate enhanced understanding of the concept and applications. Three new chapters - comprehension of nonadiabatic chemic
Many biological processes are characterized by an essentially quantum dynamical event, such as elect...
Many biological processes are characterized by an essentially quantum dynamical event, such as elect...
We report the results of a theoretical/computational research program to develop methods and to inve...
Extensions of traditional molecular dynamics to excited electronic states and non-Born{Oppenheimer d...
Ionization and/or fragmentation of large organic molecules in strong laser fields can be quantitativ...
CONSPECTUS: Recent developments in nonadiabatic dynamics enabled ab inito simulations of complex ult...
The usual quantum mechanical derivation of transition state theory is a statistical one (a quasi-equ...
The usual quantum mechanical derivation of transition state theory is a statistical one (a quasi-equ...
The subject of chemical dynamics typically consists of two steps. The first is the study of the beha...
Due to their very nature, ultrafast phenomena are often accompanied by the occurrence of nonadiabati...
Photoinduced processes play a crucial role in a multitude of important molecular phenomena. Accurate...
Many biological processes are characterized by an essentially quantum dynamical event, such as elect...
Many biological processes are characterized by an essentially quantum dynamical event, such as elect...
Many biological processes are characterized by an essentially quantum dynamical event, such as elect...
By utilizing the time-independent semiclassical phase integral, we obtained modified coupled time-de...
Many biological processes are characterized by an essentially quantum dynamical event, such as elect...
Many biological processes are characterized by an essentially quantum dynamical event, such as elect...
We report the results of a theoretical/computational research program to develop methods and to inve...
Extensions of traditional molecular dynamics to excited electronic states and non-Born{Oppenheimer d...
Ionization and/or fragmentation of large organic molecules in strong laser fields can be quantitativ...
CONSPECTUS: Recent developments in nonadiabatic dynamics enabled ab inito simulations of complex ult...
The usual quantum mechanical derivation of transition state theory is a statistical one (a quasi-equ...
The usual quantum mechanical derivation of transition state theory is a statistical one (a quasi-equ...
The subject of chemical dynamics typically consists of two steps. The first is the study of the beha...
Due to their very nature, ultrafast phenomena are often accompanied by the occurrence of nonadiabati...
Photoinduced processes play a crucial role in a multitude of important molecular phenomena. Accurate...
Many biological processes are characterized by an essentially quantum dynamical event, such as elect...
Many biological processes are characterized by an essentially quantum dynamical event, such as elect...
Many biological processes are characterized by an essentially quantum dynamical event, such as elect...
By utilizing the time-independent semiclassical phase integral, we obtained modified coupled time-de...
Many biological processes are characterized by an essentially quantum dynamical event, such as elect...
Many biological processes are characterized by an essentially quantum dynamical event, such as elect...
We report the results of a theoretical/computational research program to develop methods and to inve...