10.6084/m9.figshare.1012427.v1
R Ma
R
Ma
S Yase
S
Yase
K Nagaya
K
Nagaya
K Ueda
K
Ueda
A Yamada
A
Yamada
H Fukuzawa
H
Fukuzawa
S Mondal
S
Mondal
K L Ishikawa
K
L Ishikawa
K Motomura
K
Motomura
Y Mizoguchi
Y
Mizoguchi
(a) Amplitude ratio <em>W</em> and (b) phase-shift difference (relative phase) Δ extracted from experimental PADs (red diamonds) and calculated from wavefunctions obtained by TDSE simulations (black bullets)
IOP Publishing
2013
amplitude ratios
photon energies
Rydberg manifold
sase
TDSE simulations
Photon energy
ionization
continuum wave packet
femtosecond pulses
velocity map imaging spectrometer
helium atoms
Amplitude ratio W
pad
continuum wave packets
pulse shape
Atomic Physics
Molecular Physics
2013-08-13 00:00:00
Figure
https://iop.figshare.com/articles/figure/_a_Amplitude_ratio_em_W_em_and_b_phase_shift_difference_relative_phase_extracted_from_experimental_P/1012427
<p><strong>Figure 3.</strong> (a) Amplitude ratio <em>W</em> and (b) phase-shift difference (relative phase) Δ extracted from experimental PADs (red diamonds) and calculated from wavefunctions obtained by TDSE simulations (black bullets). Theoretical scattering phase-shift difference Δ<sub>sc</sub> [<a href="http://iopscience.iop.org/0953-4075/46/16/164018/article#jpb461347bib49" target="_blank">49</a>] is represented by a blue solid line in panel (b).</p> <p><strong>Abstract</strong></p> <p>The two-photon ionization of helium atoms by ultrashort extreme-ultraviolet free-electron laser pulses, produced by the SPring-8 Compact SASE Source test accelerator, was investigated at photon energies of 20.3, 21.3, 23.0 and 24.3 eV. The angular distribution of photoelectrons generated by two-photon ionization is obtained using a velocity map imaging spectrometer. The phase-shift differences and amplitude ratios of the outgoing s and d continuum wave packets are extracted from the photoelectron angular distributions. The obtained values of the phase-shift differences are distinct from scattering phase-shift differences when the photon energy is tuned to a resonance with an excited level or Rydberg manifold. The difference stems from the co-presence of resonant and non-resonant path contributions in the two-photon ionization by femtosecond pulses. Since the relative contribution of both paths can be controlled in principle by the pulse shape, these results illustrate a new way to tailor the continuum wave packet.</p>