# Electron emission perpendicular to polarization direction in laser   assisted XUV atomic ionization

**Authors:** A. A. Gramajo, R. Della Picca, D. G. Arb\'o

arXiv: 1703.09585 · 2017-08-23

## TL;DR

This paper investigates the perpendicular electron emission in laser-assisted XUV ionization of hydrogen, revealing interference effects and sideband formation through a semiclassical model validated by quantum calculations.

## Contribution

It introduces a simple semiclassical model to interpret perpendicular electron emission and interference patterns in laser-assisted XUV ionization, aligning well with quantum results.

## Key findings

- Interference patterns explained by intra- and intercycle trajectories
- Destructive interhalfcycle interference causes characteristic sidebands
- Good agreement between semiclassical and quantum simulations

## Abstract

We present a theoretical study of ionization of the hydrogen atom due to an XUV pulse in the presence of an IR laser with both fields linearly polarized in the same direction. In particular, we study the energy distribution of photoelectrons emitted perpendicularly to the polarization direction. By means of a very simple semiclassical model which considers electron trajectories born at different ionization times, the electron energy spectrum can be interpreted as the interplay of Intra and Intercycle interferences. The intracycle interference pattern stems from the coherent superposition of four electron trajectories giving rise to (i) interference of electron trajectories born during the same half cycle (Intrahalfcycle interference) and (ii) interference between electron trajectories born during the first half cycle with those born during the second half cycle (Interhalfcycle interference). The intercycle interference is responsible for the formation of the sidebands. We also show that the destructive interhalfcycle interference for the absorption and emission of an even number of IR laser photons is responsible for the characteristic sidebands in the perpendicular direction separated by twice the IR photon energy. We analyze the dependence of the energy spectrum on the laser intensity and the time delay between the XUV pulse and the IR laser. Finally, we show that our semiclassical simulations are in very good agreement with quantum calculations within the strong field approximation and the numerical solution of the time-dependent Schr\"odinger equation.

## Full text

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## Figures

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## References

50 references — full list in the complete paper: https://tomesphere.com/paper/1703.09585/full.md

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Source: https://tomesphere.com/paper/1703.09585