Infrared-Laser Excitation of the Internal Vibrational Mode of a Diatomic Molecule Adsorbed on a Metal Surface.

Abstract

The infrared laser excitation of the internal vibrational mode of a diatomic molecule adsorbed on a metal by electron hole excitations. Simple expressions for the populations of the vibrational levels, the mean number of vibrational quanta and the rate of energy transfer between the infrared laser and the metal surface at the steady state are derived. an equation of evolution can readily be solved numerically to determine the time necessary to reach this steady state. The criteria of applicability of the Markov approximation (which leads to the golden rule) is clearly established, where it is seen that this approximation may not be used to compute the evolution of the populations of the vibrational levels. The random phase approximation is shown to give the correct kinetic equation for the populations of the vibrational levels. The excitation of carbon monoxide adsorbed on a copper surface is analyzed quantitatively.

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Document Details

Document Type
Technical Report
Publication Date
Nov 01, 1986
Accession Number
ADA174211

Entities

People

  • Andre Peremans
  • Jacques Darville
  • Jean-marie Gilles
  • Thomas F. George

Organizations

  • University at Buffalo

Tags

Communities of Interest

  • Advanced Electronics
  • Energy and Power Technologies

DTIC Thesaurus Topics

  • Abstracts
  • Air Force
  • Carbon Monoxide
  • Chemical Engineering
  • Chemistry
  • Diatomic Molecules
  • Dielectric Gases
  • Electron Holes
  • Energy Transfer
  • Laser Beams
  • Materials
  • Materials Science
  • Military Research
  • Physics
  • Surface Reactions
  • United States
  • United States Government

Fields of Study

  • Engineering

Readers

  • Combustion science or combustion engineering.
  • Nanoscale Plasmonic Nanotechnology
  • Structural Dynamics.

Technology Areas

  • Directed Energy
  • Directed Energy - Lasers
  • Microelectronics