76 research outputs found
Elliptical Trajectories in Nonsequential Double Ionization
Using a classical ensemble method, nonsequential double ionization is
predicted to exist with elliptical and circular polarization. Recollision is
found to be the underlying mechanism and it is only possible via elliptical
trajectories.Comment: Submitted to New Journal of Physic
A quasi classical approach to fully differential ionization cross sections
A classical approximation to time dependent quantum mechanical scattering in
the M\o{}ller formalism is presented. Numerically, our approach is similar to a
standard Classical-Trajectory-Monte-Carlo calculation. Conceptually, however,
our formulation allows one to release the restriction to stationary initial
distributions. This is achieved by a classical forward-backward propagation
technique. As a first application and for comparison with experiment we present
fully differential cross sections for electron impact ionization of atomic
hydrogen in the Erhardt geometry.Comment: 6 pages, 2 figure
Electron Impact Ionization Close to the Threshold: Classical Calculations
In this paper we present Classical Trajectory Monte Carlo (CTMC) calculations
for single and multiple electron ionization of Argon atoms and ions in the
threshold region. We are able to recover the Wannier exponents a for the
power-law behavior of the cross section s versus excess energy: the exact value
of the exponent as well as the existence of its saturation for multiple
ionization appear to be related to how the total binding energy is shared
between target electrons.Comment: 9 pages. To be published in Journal of Physics
Multiple electron trapping in the fragmentation of strongly driven molecules
We present a theoretical quasiclassical study of the formation, during
Coulomb explosion, of two highly excited neutral H atoms (double H) of
strongly driven H. In this process, after the laser field is turned off
each electron occupies a Rydberg state of an H atom. We show that two-electron
effects are important in order to correctly account for double H
formation. We find that the route to forming two H atoms is similar to
pathway B that was identified in Phys. Rev. A {\bf 85} 011402 (R) as one of the
two routes leading to single H formation. However, instead of one
ionization step being "frustrated" as is the case for pathway B, both
ionization steps are "frustrated" in double H formation. Moreover, we
compute the screened nuclear charge that drives the explosion of the nuclei
during double H formation.Comment: 4 pages, 6 figure
Chaotic features in classical scattering processes between ions and atoms
A numerical study has been done of collisions between protons and hydrogen
atoms, treated as classical particles, at low impact velocities. The presence
of chaos has been looked for by investigating the processes with standard
techniques of the chaotic--scattering theory. The evidence of a sharp
transition from nearly regular scattering to fully developed chaos has been
found at the lower velocities.Comment: 10 pages, Latex, 3 figures (available upon request to the authors),
submitted to Journal of Physics
Direct versus Delayed pathways in Strong-Field Non-Sequential Double Ionization
We report full-dimensionality quantum and classical calculations for double
ionization of laser-driven helium at 390 nm. Good qualitative agreement is
observed. We show that the classical double ionization trajectories can be
divided into two distinct pathways: direct and delayed. The direct pathway,
with an almost simultaneous ejection of both electrons, emerges from small
laser intensities. With increasing intensity its relative importance, compared
to the delayed ionization pathway, increases until it becomes the predominant
pathway for total electron escape energy below around 5.25 . However the
delayed pathway is the predominant one for double ionization above a certain
cut-off energy at all laser intensities
A CTMC study of collisions between protons and molecular ions
We study numerically collisions between protons and molecular ions at
intermediate impact energies by using the Classical Trajectory Monte Carlo
method (CTMC). Total and differential cross sections are computed. The results
are compared with: a) the standard one electron--two nucleon scattering, and b)
the quantum mechanical treatment of the scattering.Comment: ReVTeX, 5 pages + 5 figs. (EPS) To be published in Physica Script
Dynamical stabilization of classical multi electron targets against autoionization
We demonstrate that a recently published quasiclassical M\oller type approach
[Geyer and Rost 2002, J. Phys. B 35 1479] can be used to overcome the problem
of autoionization, which arises in classical trajectory calculations for many
electron targets. In this method the target is stabilized dynamically by a
backward--forward propagation scheme. We illustrate this refocusing and present
total cross sections for single and double ionization of helium by electron
impact.Comment: LaTeX, 6 pages, 2 figures; submitted to J. Phys.
Ion Collisions in Very Strong Electric Fields
A Classical Trajectory Monte Carlo (CTMC) simulation has been made of
processes of charge exchange and ionization between an hydrogen atom and fully
stripped ions embedded in very strong static electric fields (
V/m), which are thought to exist in cosmic and laser--produced plasmas.
Calculations show that the presence of the field affects absolute values of the
cross sections, enhancing ionization and reducing charge exchange. Moreover,
the overall effect depends upon the relative orientation between the field and
the nuclear motion. Other features of a null-field situation, such as scaling
laws, are revisited.Comment: Latex, 13 pages, 11 figures (available upon request), to be published
in Journal of Physics
Non-dipole recollision-gated double ionization and observable effects
Using a three-dimensional semiclassical model, we study double ionization for
strongly-driven He fully accounting for magnetic field effects. For linearly
and slightly elliptically polarized laser fields, we show that recollisions and
the magnetic field combined act as a gate. This gate favors more transverse -
with respect to the electric field - initial momenta of the tunneling electron
that are opposite to the propagation direction of the laser field. In the
absence of non-dipole effects, the transverse initial momentum is symmetric
with respect to zero. We find that this asymmetry in the transverse initial
momentum gives rise to an asymmetry in a double ionization observable. Finally,
we show that this asymmetry in the transverse initial momentum of the tunneling
electron accounts for a recently-reported unexpectedly large average sum of the
electron momenta parallel to the propagation direction of the laser field.Comment: Amended the focus of the paper and discussion. 9 pages, 7 figure
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