JCE 1998 (75) 238 [Feb] Extending the Diatomic FTIR Experiment: A Computational Exercise To Calculate Potential Energy Curves


	\| Subscriptions \| Software Orders \| Support \| Contributors \| Advertisers \|

JCE Print

Current Issue
Previous Issues
Supplements
Search JCE Index

JCE Digital Library

DigiDemos
QBank
SymMath
WebWare

JCE Software

Latest Releases
Software & Video
Downloads
Support

Only@JCE Online

JCE Online Store
JCE HS CLIC
JCE Discussion Forums

Biographical Snapshots
ChemEd Resource Shelf
Featured Molecules
Hal's Picks
Project Chemlab
Reviewed WWW Sites
"Web-Ed" Articles

About JCE

Features
Publications
Operations
Outreach
Contact Us

Home > JCE Print > Journal of Chemical Education > Issues > 1998 > February >

Information • Textbooks • Media • Resources

Extending the Diatomic FTIR Experiment: A Computational Exercise To Calculate Potential Energy Curves

Osman Sorkhabi, William M. Jackson, and Iraj Daizadeh
University of California, Davis, Department of Chemistry, Davis, CA 95616

February 1998
Vol. 75 No. 2
p. 238

Table of Contents
Supplements in This Issue
Previous Article
Next Article

Full Text (PDF)

Abstract

We are proposing an extension to the classical HCl/DCl experiment for undergraduate physical chemistry courses. This extension involves calculating ro-vibrational spectra and potential energy curves for a series of diatomic molecules using the Morse function a modified-Morse function also known as the Hulburt-Hirschfelder (HH) function, and the Rydberg-Klein-Rees (RKR) method using programming languages and/or spread sheet software such as Excel or Quattro Pro. This exercise will serve as an extension to the standard IR/FTIR absorption experiment and it will tie together experimental and computational techniques, thus providing the student with a more complete picture of the system under study. To our knowledge, no other experiment incorporates calculations of potential energy curves. The uniqueness of this approach is the fact that it ties modern computational techniques with classical experiments. The above exercise was assigned as a final project to an upper division undergraduate class titled Molecular Structure and Spectroscopy at UC Davis. The students were asked to generate potential energy curves for the given diatomic molecule using the Morse, HH, and the RKR methods. Overall, the students performed very well on this project and with enthusiasm.

More Information
Citation	Sorkhabi, Osman; Jackson, William M.; Daizadeh, Iraj. J. Chem. Educ. 1998 75 238.
Keywords	Physical Chemistry, Computational Chemistry, and IR Spectroscopy
History	Created: Last Updated:	June 28, 1999 June 24, 2005


<< Previous Article	Table of Contents	Next Article >>

Home > JCE Print > Journal of Chemical Education > Issues > 1998 > February > Page 238

Subscriptions

Subscription Info
Order Forms

JCE HS CLIC

Our Secondary School editors work hard to distill all the JCE materials to produce a fraction of particular interest to high school teachers. We call it CLIC.

JCE HS CLIC

Contributions Welcome

JCE welcomes your submission

Contributors' Corner

Advertisers

In recent years we have worked hard to better match our advertisers with our readers. When shopping for chemistry education materials, visit our advertisers' WWW sites first.

Recent Advertisers

Be An Ambassador

Take JCE along on your outreach missions. Copies of the Journal, guest access to JCE Online, our publications catalog, and more are available for your participants.

Outreach with JCE


Comments to jceonline@chem.wisc.edu	Copyright © Division of Chemical Education, Inc., American Chemical Society. All rights reserved.