Problem being addressed:
Molecular movies depicting chemical reactions via attosecond (10^-18 s) snapshots, which vastly improve our understanding of molecular dynamics, is within our grasp. Strong-field imaging techniques under development, such as photoelectron holography, promise just this. However, up until very recently, all strong-field theoretical models have neglected spin, spin-orbit coupling and orbital angular momentum (OAM). Initial work including spin in the initial state, along with recent experiments, has shown that spin in strong-field processes is vitally important, leading to different ionization probabilities which in turn may alter the all important electron dynamics. Furthermore, recent work has demonstrated that the OAM of the photoelectron may be measured, providing yet another degree of freedom for exploration that is intimately connected to spin.
Impact for society:
This will enable the role of spin to be fully understood in SFP and thus fully fledged imaging protocols can be explored where the additional observable, spin, is fully accounted for and exploited.
In NSDI the combination of quantum interference, high momentum and spin correlation (possibly even entanglement) will lead to a wealth of applications in imaging and beyond, if these properties can be understood.
Overall objectives:
I will utilise and develop cutting edge theoretical frameworks to fully include electron spin, orbital angular momentum and spin-orbit coupling for strong-field processes in atoms and molecules. I will develop a semi-analytic model, which fully includes spin and spin-orbit coupling. This is motivated by the long history of semi-analytic methods that have been developed in this field, which have enabled unprecedented access into the electron dynamics for strong-field processes. As such, developing a model for spin will reveal deep new physical insight. A proper treatment allows more advanced and robust imaging techniques. I will explore the use of spin to enhance existing imaging processes, such as photoelectron holography. Furthermore, I will develop the semi-analytic model for two electrons and explore spin entanglement and correlation with momentum in two-electron ionisation processes, to design entirely new imaging procedures. This analysis will also open up the possibility of exploiting this system for quantum information purposes.