In this review, we will focus on the theoretical aspects in observing and controlling the
electronic dynamics in few-electron atoms and molecules by attosecond pulses in different …

Laser pulses with a waveform-controlled electric field and broken inversion symmetry
establish the opportunity to achieve directional control of molecular processes on a …

An intense phase-controlled orthogonally polarized two-color ultrashort laser pulse is used
to singly ionize and dissociate H 2 into a neutral hydrogen atom and a proton. Emission …

We have performed a coupled electron–nuclear dynamics study of H2+ molecular ions
under the influence of an intense few-cycle 4.5 fs laser pulse with an intensity of 4× 1014 …

Strong laser fields can be used to trigger an ultrafast molecular response that involves
electronic excitation and ionization dynamics. Here, we report on the experimental control of …

The strong coupling between intense laser fields and valence electrons in molecules causes
distortions of the potential energy hypersurfaces which determine the motion of the nuclei …

We present a theoretical study of the H 2+ molecular ion wave-packet dynamics in plasmon-
enhanced laser fields. These fields may be produced, for instance, when metallic …

We study the exact nuclear time-dependent potential energy surface (TDPES) for laser-
induced electron localization with a view to eventually developing a mixed quantum …

Few-cycle ultrashort IR pulses allow excitation of coherently coupled electronic states
toward steering nuclear motions in molecules. We include in the Hamiltonian the excitation …

We establish an energy conservation law for tunneling electrons driven by a circularly
polarized light in a rotationally invariant potential. This conservation law emerges from the …