Numerical Detector Theory for the Longitudinal Momentum Distribution of the Electron in Strong Field Ionization

The lack of analytical solutions for the exit momentum in the laser-driven tunneling theory is a well-recognized problem in strong field physics. Theoretical studies of electron momentum distributions in the neighborhood of the tunneling exit depend heavily on ad hoc assumptions. In this Letter, we...

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Veröffentlicht in:	Physical review letters 2017-05, Vol.118 (21), p.213201-213201, Article 213201
Hauptverfasser:	Tian, Justin, Wang, Xu, Eberly, J H
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creator	Tian, Justin Wang, Xu Eberly, J H
description	The lack of analytical solutions for the exit momentum in the laser-driven tunneling theory is a well-recognized problem in strong field physics. Theoretical studies of electron momentum distributions in the neighborhood of the tunneling exit depend heavily on ad hoc assumptions. In this Letter, we apply a new numerical method to study the exiting electron's longitudinal momentum distribution under intense short-pulse laser excitation. We present the first realizations of the dynamic behavior of an electron near the so-called tunneling exit region without adopting a tunneling approximation.
doi_str_mv	10.1103/PhysRevLett.118.213201
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title	Numerical Detector Theory for the Longitudinal Momentum Distribution of the Electron in Strong Field Ionization
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