Non-Adiabatic Energy Surfaces of the B+H2 Systems

Abstract

In order to solve the dynamics of a system, the kinetic energy operator of the Hamiltonian must be diagonalized. Diagonalization requires rotation of the system into a non-adiabatic representation. This rotation is a coupling angle determined by the derivative coupling terms. Derivative coupling terms are calculated using Columbus and Brooklyn, software packages. Separation of internal dynamics characterized by Jacobi coordinates, and external dynamics characterized by a set of Euler angles and the center of mass position, requires a transformation from Cartesian coordinates to Jacobi coordinates required for subsequent dynamical calculations. Previous attempts to solve for non-adiabatic energy surfaces in this manner have failed because of an ambiguity in selecting the correct variable for describing the overall rotation of the B+H2 system, giving answers that do not agree with theory. This error, which lies within the method of converting from one coordinate system to another, is discovered and corrected. By way of this correction, correct coupling angles are calculated, and non-adiabatic energy surfaces are calculated.

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Document Details

Document Type
Technical Report
Publication Date
Mar 01, 2005
Accession Number
ADA434277

Entities

People

  • Lachlan T. Belcher

Organizations

  • Air Force Institute of Technology

Tags

Communities of Interest

  • Energy and Power Technologies

DTIC Thesaurus Topics

  • Air Force
  • Angular Momentum
  • Atomic Orbitals
  • Cartesian Coordinates
  • Chemical Reactions
  • Chemistry
  • Coordinate Systems
  • Differential Equations
  • Eigenvalues
  • Eigenvectors
  • Energy Levels
  • Equations
  • Exclusion Principle
  • Ground State
  • Quantum Chemistry
  • Wave Equations
  • Wave Functions

Fields of Study

  • Physics

Readers

  • Approximation Theory.
  • Control Systems Engineering.
  • Quantum spin resonance or Electron Paramagnetic Resonance spectroscopy.