The response of a neutral atom to a strong laser field probed by transient absorption near the ionisation threshold
File(s)1512.07652v1.pdf (1.06 MB)
Accepted version
Author(s)
Type
Working Paper
Abstract
We present transient absorption spectra of an extreme ultraviolet attosecond
pulse train in helium dressed by an 800 nm laser field with intensity ranging
from $2\times10^{12}$ W/cm$^2$ to $2\times10^{14}$ W/cm$^2$. The energy range
probed spans 16-42 eV, straddling the first ionisation energy of helium (24.59
eV). By changing the relative polarisation of the dressing field with respect
to the attosecond pulse train polarisation we observe a large change in the
modulation of the absorption reflecting the vectorial response to the dressing
field. With parallel polarized dressing and probing fields, we observe
significant modulations with periods of one half and one quarter of the
dressing field period. With perpendicularly polarized dressing and probing
fields, the modulations of the harmonics above the ionisation threshold are
significantly suppressed. A full-dimensionality solution of the single-atom
time-dependent Schr\"odinger equation obtained using the recently developed
ab-initio time-dependent B-spline ADC method reproduce some of our
observations.
pulse train in helium dressed by an 800 nm laser field with intensity ranging
from $2\times10^{12}$ W/cm$^2$ to $2\times10^{14}$ W/cm$^2$. The energy range
probed spans 16-42 eV, straddling the first ionisation energy of helium (24.59
eV). By changing the relative polarisation of the dressing field with respect
to the attosecond pulse train polarisation we observe a large change in the
modulation of the absorption reflecting the vectorial response to the dressing
field. With parallel polarized dressing and probing fields, we observe
significant modulations with periods of one half and one quarter of the
dressing field period. With perpendicularly polarized dressing and probing
fields, the modulations of the harmonics above the ionisation threshold are
significantly suppressed. A full-dimensionality solution of the single-atom
time-dependent Schr\"odinger equation obtained using the recently developed
ab-initio time-dependent B-spline ADC method reproduce some of our
observations.
Date Issued
2015-12-23
Citation
2015
Copyright Statement
© The Author(s) 2015.
Sponsor
Engineering & Physical Science Research Council (EPSRC)
Identifier
http://arxiv.org/abs/1512.07652v1
Grant Number
EP/I032517/1
Subjects
physics.atom-ph
physics.atom-ph
Notes
9 pages, 5 figures