Photodetachment of H- near a hard wall with arbitrary laser polarization direction

doi:10.1088/1674-1056/24/8/083201

Abstract The photodetachment of H^- near a hard wall is investigated with linear polarized laser light travelling in arbitrary direction θ_L with respect to the z axis. An analytical formula for the total cross section is derived using semi-classical closed orbit theory, which consists of two terms, i.e., the smooth background term and the oscillatory term with an extra factor 2(θ_L). This factor controls oscillations in the total photodetachment cross section. The amplitude of oscillation is maximum at θ_L=0 when the laser polarization direction is perpendicular to the wall and it approaches zero at θ_L=π/2 when the laser polarization direction is parallel to the wall. It is also observed that the total cross section depends on the source–wall distance and it reduces to a free space case when the wall is at infinite distance from the source.

Keywords: quantum interference photodetachment process hard wall closed orbit theory

Received: 07 November 2014
Revised: 04 March 2015
Accepted manuscript online:

PACS:	32.80.Gc	(Photodetachment of atomic negative ions)
	03.65.Sq	(Semiclassical theories and applications)
	68.65.Fg	(Quantum wells)
	32.60.+i	(Zeeman and Stark effects)

Corresponding Authors: Azmat Iqbal
E-mail: azmatiqbal786@gmail.com

Cite this article:

Azmat Iqbal, A. Afaq Photodetachment of H^- near a hard wall with arbitrary laser polarization direction 2015 Chin. Phys. B 24 083201

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Photodetachment of H- near a hard wall with arbitrary laser polarization direction

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Photodetachment of H^- near a hard wall with arbitrary laser polarization direction