TIGER

Journal Articles: 44 results
Calcium Carbonate  Jay A. Young
The hazards of calcium carbonate are discussed.
Young, Jay A. J. Chem. Educ. 2007, 84, 1102.
Ionic Bonding |
Laboratory Management
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
Entropy and the Shelf Model: A Quantum Physical Approach to a Physical Property  Arnd H. Jungermann
A quantum physical approach relying on energy quantization leads to three simple rules which are the key to understanding the physical property described by molar entropy values.
Jungermann, Arnd H. J. Chem. Educ. 2006, 83, 1686.
Alcohols |
Alkanes / Cycloalkanes |
Carboxylic Acids |
Covalent Bonding |
Ionic Bonding |
Physical Properties |
Quantum Chemistry |
Thermodynamics
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LUMO 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
Effects of Exchange Energy and Spin-Orbit Coupling on Bond Energies  Derek W. Smith
It is shown that the ground states of atoms having pn configurations are stabilized by exchange energy (n = 2, 3, or 4) and/or spinorbit coupling (n = 1, 2, 4, or 5).
Smith, Derek W. J. Chem. Educ. 2004, 81, 886.
Atomic Properties / Structure |
Main-Group Elements |
Molecular Properties / Structure |
Periodicity / Periodic Table |
Descriptive Chemistry |
Ionic Bonding |
Covalent Bonding |
Metallic Bonding
The Concept of Ionic Strength Eighty Years after Its Introduction in Chemistry  Manuel E. Sastre de Vicente
Even today, eighty years after its empirical introduction in chemistry, the ionic strength of a solution continues to be regarded as a major variable in examining salt effects in many fields of science.
Sastre de Vicente, Manuel E. J. Chem. Educ. 2004, 81, 750.
Ionic Bonding |
Aqueous Solution Chemistry |
Electrochemistry
The Noble Gas Configuration—Not the Driving Force but the Rule of the Game in Chemistry  Roland Schmid
Explains the covalent and ionic bonding behavior of main-group elements in terms of electromagnetic forces rather than the supposed "stability" of noble-gas configurations.
Schmid, Roland. J. Chem. Educ. 2003, 80, 931.
Molecular Modeling |
Periodicity / Periodic Table |
Main-Group Elements |
Atomic Properties / Structure |
Reactions |
Covalent Bonding |
Ionic Bonding
Lattice Energetics  William J. Vining, Robert P. Grosso, Jr., and Justin T. Fermann
Software to help students understand the energetics and interactions between ions in a crystalline solid; found on the Advanced Chemistry Collection CD-ROM, 3rd Edition.
Vining, William J.; Grosso, Robert P., Jr.; Fermann, Justin T. J. Chem. Educ. 2003, 80, 108.
Molecular Properties / Structure |
Solid State Chemistry |
Crystals / Crystallography |
Ionic Bonding
Electron Densities, Atomic Charges, and Ionic, Covalent and Polar Bonds  Ronald J. Gillespie
The terms ionic and covalent character are vague, qualitative, and ill-defined. In contrast, the analysis of the electron density by the AIM theory leads to clearly defined quantitative properties such as the charges on the atoms and the electron density at the bond critical point that provide a sound basis for discussing bonding and geometry.
Gillespie, Ronald J. J. Chem. Educ. 2001, 78, 1688.
Computational Chemistry |
Molecular Properties / Structure |
Theoretical Chemistry |
Ionic Bonding |
Covalent Bonding
Electronegativity and Bond Type: Predicting Bond Type  Gordon Sproul
Important limitations with using electronegativity differences to determine bond type and recommendations for using electronegativities in general chemistry.
Sproul, Gordon. J. Chem. Educ. 2001, 78, 387.
Covalent Bonding |
Materials Science |
Periodicity / Periodic Table |
Ionic Bonding |
Atomic Properties / Structure |
Metallic Bonding
Should Gaseous BF3 and SiF4 Be Described as Ionic Compounds?  Arne Haaland, Trygve Helgaker, Kenneth Ruud, and D. J. Shorokhov
Analysis suggesting that representing BF3 and SiF3 as ionic compounds may be misleading.
Haaland, Arne; Helgaker, Trygve; Ruud, Kenneth; Shorokhov, D. J. J. Chem. Educ. 2000, 77, 1076.
Molecular Properties / Structure |
Covalent Bonding |
Ionic Bonding
The Bond Valence Model as a Tool for Teaching Inorganic Chemistry: The Ionic Model Revisited  I. David Brown
This paper shows how the ionic model can be used to explore the structural, chemical, and physical properties of inorganic compounds, including their stability and solubility.
Brown, I. David. J. Chem. Educ. 2000, 77, 1070.
Ionic Bonding |
Materials Science |
Solid State Chemistry |
Theoretical Chemistry |
Water / Water Chemistry
Ionic Crystals: A Simple and Safe Lecture Demonstration of the Preparation of NaI from Its Elements  Zelek S. Herman
A simple and safe classroom demonstration showing the production of sodium iodide (NaI) crystals from elemental sodium and elemental (molecular) iodine is presented. The demonstration, which is quite impressive, naturally fits into the discussion of ionic bonding and the alkali halide crystals.
Herman, Zelek S. J. Chem. Educ. 2000, 77, 619.
Crystals / Crystallography |
Thermodynamics |
Ionic Bonding |
Crystals / Crystallography
Reply to Coulombic Models in Chemical Bonding  Smith, Derek W.
Coulombic vs molecular orbital models for explaining the molecular shapes of ionic molecules.
Smith, Derek W. J. Chem. Educ. 2000, 77, 445.
Ionic Bonding |
Molecular Modeling |
Molecular Properties / Structure |
MO Theory
Coulombic Models in Chemical Bonding  Sacks, Lawrence J.
Coulombic vs molecular orbital models for explaining the molecular shapes of ionic molecules.
Sacks, Lawrence J. J. Chem. Educ. 2000, 77, 445.
Ionic Bonding |
Molecular Modeling |
Molecular Properties / Structure |
MO Theory
Hydrogen Bonds Involving Transition Metal Centers Acting As Proton Acceptors  Antonio Martín
A short review of the most remarkable results which have recently reported M----H-X hydrogen bonds, along with a systematization of their structural and spectroscopic properties, is provided in this paper. These M----H interactions are substantially different from the "agostic" M----H ones, and their differences are commented on, setting up criteria that permit their clear differentiation in order to avoid some of the misidentifications that occurred in the past.
Tello, Antonio Martín. J. Chem. Educ. 1999, 76, 578.
Coordination Compounds |
Covalent Bonding |
Ionic Bonding |
Noncovalent Interactions |
Metals |
Organometallics |
Hydrogen Bonding
Covalent and Ionic Molecules: Why Are BeF2 and AlF3 High Melting Point Solids whereas BF3 and SiF4 Are Gases?  Ronald J. Gillespie
Calculated ionic charges show that BF3 and SiF4 are predominately ionic molecules yet in contrast to BeF2 and AlF3 they exist as gases at room temperature and form molecular solids rather than infinite three-dimensional "ionic" solids at low temperature. Whether or not ionic molecules form a three-dimensional infinite ionic lattice or a molecular solid depends more on relative atomic (ionic) sizes than on the nature of the bonding in the isolated molecule.
Gillespie, Ronald J. J. Chem. Educ. 1998, 75, 923.
Covalent Bonding |
Molecular Properties / Structure |
Solids |
Gases |
Ionic Bonding
Teaching Chemistry with Electron Density Models  Gwendolyn P. Shusterman and Alan J. Shusterman
This article describes a powerful new method for teaching students about electronic structure and its relevance to chemical phenomena. This method, developed and used for several years in general chemistry and organic chemistry courses, relies on computer-generated three-dimensional models of electron density distributions.
Shusterman, Gwendolyn P.; Shusterman, Alan J. J. Chem. Educ. 1997, 74, 771.
Learning Theories |
Computational Chemistry |
Molecular Modeling |
Quantum Chemistry |
Atomic Properties / Structure |
Covalent Bonding |
Ionic Bonding |
Noncovalent Interactions
The Role of Electrostatic Effects in Organic Chemistry  Kenneth B. Wiberg
Electrostatic effects on the properties of organic compounds are reviewed to demonstrate the importance of electronegativity differences between the atoms forming a bond. Bond dissociation energies are generally found to increase as the electronegativity difference increases, and the bonds have increased ionic character.
Wiberg, Kenneth B. J. Chem. Educ. 1996, 73, 1089.
Atomic Properties / Structure |
Covalent Bonding |
Ionic Bonding
Salts are Mostly Not Ionized  Stephen J. Hawkes
The popular assumption that all salts are totally ionized in aqueous solution is false. Moreover, it is approximated only by alkali metal salts and by salts of alkaline earth metals with high atomic numbers.
Hawkes, Stephen J. J. Chem. Educ. 1996, 73, 421.
Ionic Bonding |
Metals |
Solutions / Solvents
Bond Energy Data Summarized  Kildahl, Nicholas K.
A periodic table that summarizes a variety of bond energy information.
Kildahl, Nicholas K. J. Chem. Educ. 1995, 72, 423.
Periodicity / Periodic Table |
Covalent Bonding |
Ionic Bonding
A Quantitative van Arkel Diagram  Jensen, William B.
Using van Arkel diagrams to schematically represent relationships between ionic, covalent, and metallic bonds.
Jensen, William B. J. Chem. Educ. 1995, 72, 395.
Covalent Bonding |
Ionic Bonding |
Metallic Bonding
Classifying Substances by Electrical Character: An Alternative to Classifying by Bond Type  Nelson, P. G.
An alternative classification of substances based on their electrical properties.
Nelson, P. G. J. Chem. Educ. 1994, 71, 24.
Conductivity |
Covalent Bonding |
Ionic Bonding |
Metallic Bonding |
Semiconductors
Why Low Melting Does Not Indicate Covalency in MX4 Compounds: Examining the Importance of Crystal Structure in the Behavior of Solids  Lingafelter, Edward C.
A summary of the importance of relative ionic sizes and coordination numbers in determining the behavior of solids from prior papers by Pauling and Kossel.
Lingafelter, Edward C. J. Chem. Educ. 1993, 70, 98.
Solids |
Ionic Bonding |
Covalent Bonding |
Kinetic-Molecular Theory |
Enrichment / Review Materials
The solvation of halide ions and its chemical significance  Sharpe, Alan G.
Most of this article is concerned with structural and thermodynamic aspects of halide ion solvation, first by water and the by other solvents.
Sharpe, Alan G. J. Chem. Educ. 1990, 67, 309.
Solutions / Solvents |
Thermodynamics |
Ionic Bonding
Lattice enthalpies of ionic halides, hydrides, oxides, and sulfides: Second-electron affinities of atomic oxygen and sulfur  Holbrook, Jack B.; Sabry-Grant, Ralph; Smith, Barry C.; Tandel, Thakor V.
These simple empirical relationships which allow lattice enthalpies of ionic compounds to be determined readily from observed internuclear separations are investigated here.
Holbrook, Jack B.; Sabry-Grant, Ralph; Smith, Barry C.; Tandel, Thakor V. J. Chem. Educ. 1990, 67, 304.
Calorimetry / Thermochemistry |
Atomic Properties / Structure |
Ionic Bonding
Critical behavior in the solubility of ionic compounds  Gillispie, Gregory D.
The process of an ionic compound dissolving in a pure solvent is a convenient way to introduce Debye-Huckel activity coefficients.
Gillispie, Gregory D. J. Chem. Educ. 1990, 67, 143.
Solutions / Solvents |
Ionic Bonding |
Electrolytic / Galvanic Cells / Potentials
Ionic crystals and electrostatics: The cluster model versus the standard model  Recio, J. M.; Luana, V.; Pueyo, L.
In these studies both semiemperical and ab initio approaches have been worked out.
Recio, J. M.; Luana, V.; Pueyo, L. J. Chem. Educ. 1989, 66, 307.
Ionic Bonding |
Crystals / Crystallography |
Electrochemistry
Ion association, solubilities, and reduction potentials in aqueous solution  Russo, Steven O.; Hanania, George I. H.
It is the author's belief that a combined approach to ionic activity and ion association presents to the student a realistic and more quantitative view of electrolyte solutions than is otherwise possible.
Russo, Steven O.; Hanania, George I. H. J. Chem. Educ. 1989, 66, 148.
Aqueous Solution Chemistry |
Electrolytic / Galvanic Cells / Potentials |
Ionic Bonding |
Oxidation / Reduction
An ionic model for metallic bonding  Rioux, Frank
The tangent spheres approach, combined with several simplifying assumptions, enables one to calculate the lattice energy, the lattice constant and the density of metals.
Rioux, Frank J. Chem. Educ. 1985, 62, 383.
Ionic Bonding |
Metallic Bonding |
Physical Properties
A needed replacement for the customary description of chemical bonding  Sanderson, R. T.
Description of and encouragement to use an alternative to the covalent / ionic model for chemical bonding.
Sanderson, R. T. J. Chem. Educ. 1982, 59, 376.
Covalent Bonding |
Ionic Bonding
One-dimensional K2Pt(CN)4BrO 3H20. A structure containing five different types of bonding  Masuo, Steven T.; Miller, Joel S.; Gebert, Elizabeth; Reis, Arthur H., Jr.
Examples of the five types of bonding found in matter and there manifestations in the title compound.
Masuo, Steven T.; Miller, Joel S.; Gebert, Elizabeth; Reis, Arthur H., Jr. J. Chem. Educ. 1982, 59, 361.
Coordination Compounds |
Covalent Bonding |
Ionic Bonding |
Metallic Bonding |
Hydrogen Bonding
A bonding parameter. II, Rock salt and cesium chloride crystal structures  Elson, Jesse
It is the purpose of this study to compare the rock salt and cesium chloride structures of the alkali halogenides.
Elson, Jesse J. Chem. Educ. 1969, 46, 28.
Crystals / Crystallography |
Solids |
Ionic Bonding
Hard and soft acids and bases, HSAB, part II: Underlying theories  Pearson, Ralph G.
Explores possible explanations for and presents applications of the principles of hard and soft acids and bases.
Pearson, Ralph G. J. Chem. Educ. 1968, 45, 643.
Acids / Bases |
Lewis Acids / Bases |
Aqueous Solution Chemistry |
Solutions / Solvents |
Ionic Bonding |
Covalent Bonding
Why does methane burn?  Sanderson, R. T.
A thermodynamic explanation for why methane burns.
Sanderson, R. T. J. Chem. Educ. 1968, 45, 423.
Thermodynamics |
Reactions |
Oxidation / Reduction |
Calorimetry / Thermochemistry |
Covalent Bonding |
Ionic Bonding
The nature of " ionic" solids: The coordinated polymeric model  Sanderson, R. T.
The author discusses and questions the validity of considering some solids as purely ionic and offers the coordinated polymeric model as a plausible alternative.
Sanderson, R. T. J. Chem. Educ. 1967, 44, 516.
Solids |
Ionic Bonding
Tangent-sphere models of molecules. III. Chemical implications of inner-shell electrons  Bent, Henry A.
While a study of atomic core sizes might seem to hold little promise of offering interesting insights into the main body of chemical theory, it is demonstrated here that from such a study emerges a picture of chemical bonding that encompasses as particular cases covalent, ionic, and metallic bonds.
Bent, Henry A. J. Chem. Educ. 1965, 42, 302.
Atomic Properties / Structure |
Molecular Properties / Structure |
Molecular Modeling |
Covalent Bonding |
Ionic Bonding |
Metallic Bonding
Reaction heats and bond strengths (Mortimer, C. T.)  Lacher, John R.

Lacher, John R. J. Chem. Educ. 1964, 41, A130.
Thermodynamics |
Covalent Bonding |
Ionic Bonding |
Metallic Bonding
Atomic structure and chemical bonding (Seel, F.; Greenwood, N. N.; Stadler, H. P.)  Murmann, R. Kent

Murmann, R. Kent J. Chem. Educ. 1964, 41, 518.
Atomic Properties / Structure |
Covalent Bonding |
Metallic Bonding |
Ionic Bonding |
Noncovalent Interactions
Principles of chemical reaction  Sanderson, R. T.
The purpose of this paper is to examine the nature of chemical change in the hope of recognizing and setting forth the basic principles that help us to understand why they occur.
Sanderson, R. T. J. Chem. Educ. 1964, 41, 13.
Reactions |
Thermodynamics |
Mechanisms of Reactions |
Kinetics |
Synthesis |
Covalent Bonding |
Ionic Bonding |
Metallic Bonding
A classical electrostatic view of chemical forces  Jaffe, H. H.
This paper reviews the different types of forces involved in the formation of chemical compounds, solids and liquids.
Jaffe, H. H. J. Chem. Educ. 1963, 40, 649.
Covalent Bonding |
Ionic Bonding |
Metallic Bonding |
Noncovalent Interactions
Inorganic infrared spectroscopy  Ferraro, John R.
Focuses on the use of infrared spectroscopy in solving various problems in inorganic chemistry.
Ferraro, John R. J. Chem. Educ. 1961, 38, 201.
Spectroscopy |
IR Spectroscopy |
Coordination Compounds |
Molecular Properties / Structure |
Organometallics |
Ionic Bonding |
Covalent Bonding
Comparative organic chemistry: Carbon and silicon  Wilk, I. J.
Contrasts silicone chemistry with that of regular organic compounds.
Wilk, I. J. J. Chem. Educ. 1957, 34, 463.
Covalent Bonding |
Ionic Bonding |
Mechanisms of Reactions |
Stereochemistry
The electron as an element  Ramsay, W.
Reprint of a short article examining the bonding of sodium and chlorine.
Ramsay, W. J. Chem. Educ. 1953, 30, 2.
Ionic Bonding