TIGER

Journal Articles: 12 results
Lewis Structure Representation of Free Radicals Similar to ClO  Warren Hirsch and Mark Kobrak
An unconventional Lewis structure is proposed to explain the properties of the free radical ClO and a series of its isoelectronic analogues, particularly trends in the spin density of these species.
Hirsch, Warren; Kobrak, Mark. J. Chem. Educ. 2007, 84, 1360.
Atmospheric Chemistry |
Computational Chemistry |
Covalent Bonding |
Free Radicals |
Lewis Structures |
Molecular Modeling |
MO Theory |
Valence Bond Theory
Predicting the Stability of Hypervalent Molecules  Tracy A. Mitchell, Debbie Finocchio, and Jeremy Kua
In this exercise, students use concepts in thermochemistry such as bond energy, ionization potentials, and electron affinities to predict the relative stability of two hypervalent molecules (PF5 and PH5) relative to their respective non-hypervalent counterparts.
Mitchell, Tracy A.; Finocchio, Debbie; Kua, Jeremy. J. Chem. Educ. 2007, 84, 629.
Computational Chemistry |
Covalent Bonding |
Ionic Bonding |
Lewis Structures |
Molecular Modeling |
Calorimetry / Thermochemistry |
Molecular Properties / Structure
Valence, Oxidation Number, and Formal Charge: Three Related but Fundamentally Different Concepts  Gerard Parkin
The purpose of this article is to clarify the terms valence, oxidation number, coordination number, formal charge, and number of bonds and illustrate how the valence of an atom in a molecule provides a much more meaningful criterion for establishing the chemical reasonableness of a molecule than does the oxidation number.
Parkin, Gerard. J. Chem. Educ. 2006, 83, 791.
Coordination Compounds |
Covalent Bonding |
Lewis Structures |
Oxidation State |
Nomenclature / Units / Symbols
Electronegativity and the Bond Triangle  Terry L. Meek and Leah D. Garner
The dependence of bond type on two parameters, electronegativity difference (??) and average electronegativity (?av), is examined. It is demonstrated that ionic character is governed by the partial charges of the bonded atoms, and metallic character by the HOMO¬ĚLUMO band gap.
Meek, Terry L.; Garner, Leah D. J. Chem. Educ. 2005, 82, 325.
Atomic Properties / Structure |
Covalent Bonding |
Metallic Bonding |
Ionic Bonding |
Main-Group Elements
An Investigation of the Value of Using Concept Maps in General Chemistry  Gayle Nicoll, Joseph S. Francisco, and Mary B. Nakhleh
Study of the degree to which students in introductory chemistry classes linked related concepts; comparisons of a class in which concept mapping was used and another in which it was not.
Nicoll, Gayle; Francisco, Joseph S.; Nakhleh, Mary B. J. Chem. Educ. 2001, 78, 1111.
Covalent Bonding |
Learning Theories
Lewis Structures in General Chemistry: Agreement between Electron Density Calculations and Lewis Structures  Gordon H. Purser
The internuclear electron densities of a series of X-O bonds (where X = P, S, or Cl) are calculated using quantum mechanics and compared to Lewis structures for which the formal charges have been minimized; a direct relationship is found between the internuclear electron density and the bond order predicted from Lewis structures in which formal charges are minimized.
Purser, Gordon H. J. Chem. Educ. 2001, 78, 981.
Covalent Bonding |
Computational Chemistry |
Molecular Properties / Structure |
Lewis Structures |
Quantum Chemistry
A Comment on Molecular Geometry   Frank J. Gomba
A method of determining the correct molecular geometry of simple molecules and ions with one central atom is proposed. While the usual method of determining the molecular geometry involves first drawing the Lewis structure, this method can be used without doing so. In fact, the Lewis structure need not be drawn at all. The Lewis structure may be drawn as the final step, with the geometry of the simple molecule or ion already established.
Gomba, Frank J. J. Chem. Educ. 1999, 76, 1732.
Covalent Bonding |
Molecular Properties / Structure |
VSEPR Theory
Lewis Structures Are Models for Predicting Molecular Structure, Not Electronic Structure  Gordon H. Purser
This article argues against a close relationship between Lewis dot structures and electron structure obtained from quantum mechanical calculations. Lewis structures are a powerful tool for structure prediction, though they are classical models of bonding and do not predict electronic structure.
Purser, Gordon H. J. Chem. Educ. 1999, 76, 1013.
Molecular Properties / Structure |
Covalent Bonding |
Computational Chemistry |
Quantum Chemistry |
MO Theory |
Learning Theories |
Lewis Structures |
Molecular Modeling
Lewis Structures of Boron Compounds Involving Multiple Bonding  Straub, Darel K.
Considers evidence for multiple bonding in boron compounds and supposed exceptions to the octet rule.
Straub, Darel K. J. Chem. Educ. 1995, 72, 494.
Lewis Structures |
Covalent Bonding
The chemical bond  DeKock, Roger L.
Overview of the chemical bond; considers ionic bonds, covalent bonds, Lewis electron dot structures, polar molecules and hydrogen bonds, and bonding in solid-state elements.
DeKock, Roger L. J. Chem. Educ. 1987, 64, 934.
Ionic Bonding |
Covalent Bonding |
Hydrogen Bonding |
Solid State Chemistry |
Lewis Structures |
Molecular Properties / Structure
Tangent-sphere models of molecules. II. Uses in Teaching  Bent, Henry A.
Tangent-sphere models can be used to represent highly strained bonds and multicentered bonds, atoms with expanded and contracted octets, inter- and intramolecular interactions, and the effects of electronegative groups, lone pairs, and multiple bonds on molecular geometry, bond properties, and chemical reactivity.
Bent, Henry A. J. Chem. Educ. 1963, 40, 523.
Molecular Properties / Structure |
Covalent Bonding
Chemical bonding and the geometry of molecules (Ryschkewitsch, George E.)  Eblin, Lawrence P.

Eblin, Lawrence P. J. Chem. Educ. 1963, 40, 441.
Molecular Properties / Structure |
Covalent Bonding