Determining Analytical Potential Energy Functions of Diatomic Molecules by Direct Fitting

The fully quantum mechanical 'direct-potential-fit' (DPF) method has become increasingly widely used in the reduction of diatomic spectra. The central problem of this method is the representation of the potential energy and Born-Oppenheimer breakdown (BOB) correction functions. There a...

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Main Author: Huang, Yiye
Format: Others
Language:en
Published: University of Waterloo 2006
Subjects:
Online Access:http://hdl.handle.net/10012/1284
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spelling ndltd-WATERLOO-oai-uwspace.uwaterloo.ca-10012-12842013-01-08T18:49:35ZHuang, Yiye2006-08-22T14:42:21Z2006-08-22T14:42:21Z20012001http://hdl.handle.net/10012/1284The fully quantum mechanical 'direct-potential-fit' (DPF) method has become increasingly widely used in the reduction of diatomic spectra. The central problem of this method is the representation of the potential energy and Born-Oppenheimer breakdown (BOB) correction functions. There are a number of problems associated with the existing method and potential forms. This thesis delineates these problems and finds solutions to some of them. In particular, it is shown that use of a different expansion variable and a new treatment of some of the expansions resolves most of the problems. These techniques have been successfully tested on the ground electronic states of the coinage metal hydrides and the Rb2 molecule. To address the problem of representing 'barrier' potential curves, a flexible new functional form, the 'double-exponential long-range' (DELR) potential function, is introduced and applied to the B barrier state of Li2. In addition, the Lambda-doubling level splitting which occurs for singlet Pi electronic states has been taken into account by extending the effective Schrodinger equation. The computer program DSPotFit developed in our laboratory for performing DPF analyses has been extended to incorporate the ability to fit the analytical potential energy functions to tunneling predissociation line widths for quasibound levels. Finally, an attempt is made to investigate whether there exists a hump in the ground state rotationless potential curve of beryllium hydride.application/pdf964184 bytesapplication/pdfenUniversity of WaterlooCopyright: 2001, Huang, Yiye. All rights reserved.ChemistrySpectroscopyPotential Energy FunctionsDirect Potential FitSchrodinger EquationBorn-Oppenheimer Breakdown Correction FunctionsLambda-DoublingDetermining Analytical Potential Energy Functions of Diatomic Molecules by Direct FittingThesis or DissertationChemistry and BiochemistryMaster of Science
collection NDLTD
language en
format Others
sources NDLTD
topic Chemistry
Spectroscopy
Potential Energy Functions
Direct Potential Fit
Schrodinger Equation
Born-Oppenheimer Breakdown Correction Functions
Lambda-Doubling
spellingShingle Chemistry
Spectroscopy
Potential Energy Functions
Direct Potential Fit
Schrodinger Equation
Born-Oppenheimer Breakdown Correction Functions
Lambda-Doubling
Huang, Yiye
Determining Analytical Potential Energy Functions of Diatomic Molecules by Direct Fitting
description The fully quantum mechanical 'direct-potential-fit' (DPF) method has become increasingly widely used in the reduction of diatomic spectra. The central problem of this method is the representation of the potential energy and Born-Oppenheimer breakdown (BOB) correction functions. There are a number of problems associated with the existing method and potential forms. This thesis delineates these problems and finds solutions to some of them. In particular, it is shown that use of a different expansion variable and a new treatment of some of the expansions resolves most of the problems. These techniques have been successfully tested on the ground electronic states of the coinage metal hydrides and the Rb2 molecule. To address the problem of representing 'barrier' potential curves, a flexible new functional form, the 'double-exponential long-range' (DELR) potential function, is introduced and applied to the B barrier state of Li2. In addition, the Lambda-doubling level splitting which occurs for singlet Pi electronic states has been taken into account by extending the effective Schrodinger equation. The computer program DSPotFit developed in our laboratory for performing DPF analyses has been extended to incorporate the ability to fit the analytical potential energy functions to tunneling predissociation line widths for quasibound levels. Finally, an attempt is made to investigate whether there exists a hump in the ground state rotationless potential curve of beryllium hydride.
author Huang, Yiye
author_facet Huang, Yiye
author_sort Huang, Yiye
title Determining Analytical Potential Energy Functions of Diatomic Molecules by Direct Fitting
title_short Determining Analytical Potential Energy Functions of Diatomic Molecules by Direct Fitting
title_full Determining Analytical Potential Energy Functions of Diatomic Molecules by Direct Fitting
title_fullStr Determining Analytical Potential Energy Functions of Diatomic Molecules by Direct Fitting
title_full_unstemmed Determining Analytical Potential Energy Functions of Diatomic Molecules by Direct Fitting
title_sort determining analytical potential energy functions of diatomic molecules by direct fitting
publisher University of Waterloo
publishDate 2006
url http://hdl.handle.net/10012/1284
work_keys_str_mv AT huangyiye determininganalyticalpotentialenergyfunctionsofdiatomicmoleculesbydirectfitting
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