Quantum over-barrier reflection effects manifested in photodetachment cross sections

The photodetachment of H− near a potential barrier is studied. A new formula is presented for the cross sections induced by a barrier. The new formula describes two quantum effects near the barrier tops. For energies near and above the barrier tops, the quantum over-barrier reflection effects are in...

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Bibliographic Details
Published inJournal of physics. B, Atomic, molecular, and optical physics Vol. 45; no. 17; pp. 175003 - 1-7
Main Authors Yang, B C, Du, M L
Format Journal Article
LanguageEnglish
Published Bristol IOP Publishing 14.09.2012
Institute of Physics
Subjects
Atomic and molecular physics
Atomic properties and interactions with photons
Barriers
closed-orbit theory
Coverings
Cross sections (physics)
Exact sciences and technology
Oscillations
Photodetachment
Photodetachment of atomic negative ions
Photon interactions with atoms
Physics
Position (location)
quantum over-barrier reflection
Reflection
Tops
Ion surface interaction
Potential barrier
Negative ions
Electric field effects
Tunnel effect
Electron photodetachment
Hydrogen ions 1 minus
Cross sections
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Summary:The photodetachment of H− near a potential barrier is studied. A new formula is presented for the cross sections induced by a barrier. The new formula describes two quantum effects near the barrier tops. For energies near and above the barrier tops, the quantum over-barrier reflection effects are included and the induced oscillations in the cross sections are still prominent; for energies near and below the barrier tops, the quantum tunnelling across barriers is taken into account and consequently the oscillations are weakened. For energies far away from the barrier tops, the new formula agrees with the standard closed-orbit theory. We demonstrate that a potential barrier of various width and location can be realized by placing a negative ion near a metal surface and applying an electric field pointing to the surface. The width and location of the barrier can be systematically changed by varying the electric field strength and the distance between the negative ion and the surface. Results are also presented for estimating the sizes and locations of the aforementioned quantum effects in the cross sections.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-1
content type line 23
ISSN:0953-4075
1361-6455
DOI:10.1088/0953-4075/45/17/175003