Analytical model for calibrating laser intensity in strong-field-ionization experiments

TL;DR: In this paper, the angle-dependent single ionization of carbon dioxide by linearly and circularly polarized pulses is investigated experimentally, and delay-dependent ionmomentum measurements from rotational wave packets can be used to test the validity of the axial recoil approximation.

TL;DR: The accurate retrieval of ϵ offers a better characterization of a laser pulse, promising a more delicate and quantitative control of the subcycle dynamics in many strong field processes.

TL;DR: In this paper, an ionization-induced plasma grating can be formed by spatially selective ionization of gases by the interference of two intersecting ultra-short laser pulses.

TL;DR: A scheme to measure laser intensity by examining the holographic structure originating from the interference between the direct and near-forward rescattering electrons in strong-field tunneling ionization, which shows that the amplitude of the oscillation minimizes when the time difference between the recollision and ionization of near- forward rescattering electron is half cycle of the fundamental driving field.

TL;DR: In this article, strong-field single ionization and double ionization of two diatomic molecules were studied and compared to Xe and Ar, using an intense ultrashort pulse Ti:sapphire laser in the $2.5 to $8.5 GHz range.

TL;DR: In this article, it was shown that momentum transfers from photons to an electron are found in atomic ionization by intense infrared laser pulses, where the indicated breakdown of the widely used dipole approximation calls for future improvement of molecular imaging and other techniques that depend on analysis of ionization signals.

TL;DR: In this paper, the parabolic adiabatic expansion approach to the problem of ionization of atomic systems in a static electric field, originally developed for the axially symmetric case [Phys. Rev. A 82, 023416 (2010), is generalized to arbitrary potentials.

TL;DR: In this paper, the Hartree-Fock wave function was applied to the analysis of tunneling ionization of a molecular ion (H${}{2}^{+}$), several homonuclear (H{}_{2}-, N${}_{ 2}-, O${} ǫ, O${}) and heteronuclear diatomic molecules, and a linear triatomic molecule (CO${}, 2}$) in a static electric field.