11 research outputs found
Multiphoton ionization and stabilization of helium in superintense xuv fields
Multiphoton ionization of helium is investigated in the superintense field
regime, with particular emphasis on the role of the electron-electron
interaction in the ionization and stabilization dynamics. To accomplish this,
we solve ab initio the time-dependent Schr\"odinger equation with the full
electron-electron interaction included. By comparing the ionization yields
obtained from the full calculations with corresponding results of an
independent-electron model, we come to the somewhat counterintuitive conclusion
that the single-particle picture breaks down at superstrong field strengths. We
explain this finding from the perspective of the so-called Kramers-Henneberger
frame, the reference frame of a free (classical) electron moving in the field.
The breakdown is tied to the fact that shake-up and shake-off processes cannot
be properly accounted for in commonly used independent-electron models. In
addition, we see evidence of a change from the multiphoton to the shake-off
ionization regime in the energy distributions of the electrons. From the
angular distribution it is apparent that correlation is an important factor
even in this regime
Quantitative modeling of spin relaxation in quantum dots
We use numerically exact diagonalization to calculate the spin-orbit and
phonon-induced triplet-singlet relaxation rate in a two-electron quantum dot
exposed to a tilted magnetic field. Our scheme includes a three-dimensional
description of the quantum dot, the Rashba and the linear and cubic Dresselhaus
spin-orbit coupling, the ellipticity of the quantum dot, and the full angular
description of the magnetic field. We are able to find reasonable agreement
with the experimental results of Meunier et al. [Phys. Rev. Lett. 98, 126601
(2007)] in terms of the singlet-triplet energy splitting and the spin
relaxation rate, respectively. We analyze in detail the effects of the
spin-orbit factors, magnetic-field angles, and the dimensionality, and discuss
the origins of the remaining deviations from the experimental data
Direct two-photon double ionization of H2
We have studied the process of direct (nonsequential) two-photon double ionization of molecular hydrogen (H2). Solving the time-dependent Schr¨odinger equation by an ab initio method, total (generalized) and singledifferential cross sections are obtained at photon energies from 26 to 33 eV. Both parallel and perpendicular orientation of the molecule with respect to the laser polarization direction are considered, and the results are compared with previously calculated cross sections at 30 eV, as well as the predictions of a simple model
Femtosecond-pulse-train ionization of Rydberg wave packets
We calculate, based on first-order perturbation theory, the total and differential ionization probabilities from a dynamic periodic Rydberg wave packet of a given n-shell exposed to a train of femtosecond laser pulses. The total probability is shown to depend crucially on the laser repetition rate: For certain frequencies the ionization probability vanishes, while for others it becomes very large. The origin of this effect is the strong dependence of the ionization probability on the Stark quantum number. Correspondingly, the angular electronic distribution also changes significantly with the increasing number of pulses for certain repetition rates