Photoelectron holography constitutes a powerful tool for the ultrafast imaging of matter, as it
combines high electron currents with subfemtosecond resolution, and gives information …

Advancements in light engineering have led to the creation of pulsed laser sources capable
of delivering high-repetition-rate, high-power few-cycle laser pulses across a wide spectral …

Feynman's path integral approach is to sum over all possible spatiotemporal paths to
reproduce the quantum wave function and the corresponding time evolution, which has …

Since 2001 and the first demonstrations of the feasibility of generating and measuring
attosecond light pulses, attosecond science has developed into a very active and quickly …

Interaction of intense laser fields with atoms distorts the bound-state electron cloud. Tracing
the temporal response of the electron cloud to the laser field is of fundamental importance …

Laser-induced electron tunneling ionization from atoms and molecules plays as the trigger
for a broad class of interesting strong-field phenomena in attosecond community …

Laser-induced electron tunneling underlies numerous emerging spectroscopic techniques
to probe attosecond electron dynamics in atoms and molecules. The improvement of those …

The calculation of accurate photoelectron spectra (PES) for strong-field laser-atom
experiments is a demanding computational task, even in single-active-electron …

Electrons detached from atoms by photoionization carry valuable information about light-
atom interactions. Characterizing and shaping the electron wave function on its natural …

Laser-induced tunneling ionization is one of the fundamental light-matter interaction
processes. An accurate description of the tunnel-ionized electron wave packet is central to …