Abstract
Laser induced ultrafast demagnetization is the process whereby the magnetic moment of a ferromagnetic material is seen to drop significantly on a timescale of 10–100 s of femtoseconds due to the application of a strong laser pulse. If this phenomenon can be harnessed for future technology, it offers the possibility for devices operating at speeds several orders of magnitude faster than at present. A key component to successful transfer of such a process to technology is the controllability of the process, i.e. that it can be tuned in order to overcome the practical and physical limitations imposed on the system. In this paper, we demonstrate that the spin–orbit mediated form of ultrafast demagnetization recently investigated (Krieger et al 2015 J. Chem. Theory Comput. 11 4870) by ab initio time-dependent density functional theory (TDDFT) can be controlled. To do so we use quantum optimal control theory (OCT) to couple our TDDFT simulations to the optimization machinery of OCT. We show that a laser pulse can be found which maximizes the loss of moment within a given time interval while subject to several practical and physical constraints. Furthermore we also include a constraint on the fluence of the laser pulses and find the optimal pulse that combines significant demagnetization with a desire for less powerful pulses. These calculations demonstrate optimal control is possible for spin–orbit mediated ultrafast demagnetization and lays the foundation for future optimizations/simulations which can incorporate even more constraints.
Highlights
Control of quantum dynamics using tailored laser pulses is a long standing goal of modern physics[1,2,3,4,5,6,7] as it opens up a whole new world of possibilities for future technologies
Optimal control theory (OCT) can be extended to the realm of quantum mechanics by constructing the target functional using observables given by the time-dependent schrodinger equation (TDSE)
In summary we have successfully demonstrated that optimal control of spin-orbit mediated ultrafast demagnetization is possible
Summary
Control of quantum dynamics using tailored laser pulses is a long standing goal of modern physics[1,2,3,4,5,6,7] as it opens up a whole new world of possibilities for future technologies. Smaller, and more efficient devices could be constructed if we could master control over the charge and spin dynamics of electrons on the nanoscale[8]. Precisely at these very short length and time scales, quantum effects are strong, which makes it difficult to exert this control. OCT can be extended to the realm of quantum mechanics by constructing the target functional using observables given by the time-dependent schrodinger equation (TDSE). Composed of the kinetic energy, T, the electron-electron interaction, Vee, and the external potential, Vext, which includes both the electron-nuclear interaction and the electric fields of any laser pulses.
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