TIGER

Journal Articles: 28 results
Using Molecular Dynamics Simulation To Reinforce Student Understanding of Intermolecular Forces  Phillip R. Burkholder, Gordon H. Purser, and Renee S. Cole
This article presents a series of experiments incorporating molecular dynamics simulations which predict the motion of chemical species based on the application of empirical rules and a physical analysis of the forces that act between the species. These motions can then be shown in vivid graphical form.
Burkholder, Phillip R.; Purser, Gordon H.; Cole, Renee S. J. Chem. Educ. 2008, 85, 1071.
Computational Chemistry |
Hydrogen Bonding |
Molecular Mechanics / Dynamics |
Physical Properties |
Solutions / Solvents
Popcorn—What's in the Bag?  Marissa B. Sherman and Thomas A. Evans
Three independent activities explore microwave popcorn, the nature of the packaging, and the popcorn produced.
Sherman, Marissa B.; Evans, Thomas A. J. Chem. Educ. 2006, 83, 416A.
Carbohydrates |
Nutrition |
Physical Properties |
Solutions / Solvents |
Water / Water Chemistry
Intermolecular and Intramolecular Forces: A General Chemistry Laboratory Comparison of Hydrogen Bonding in Maleic and Fumaric Acids  Frazier W. Nyasulu and John Macklin
This article presents a simple laboratory experiment that is designed to enhance students' understanding of inter- and intramolecular hydrogen bonding by demonstrating the comparative effect of these phenomena on some chemical and physical properties.
Nyasulu, Frazier W.; Macklin, John. J. Chem. Educ. 2006, 83, 770.
Acids / Bases |
Hydrogen Bonding |
Noncovalent Interactions |
Thermodynamics |
Titration / Volumetric Analysis
The Nature of Hydrogen Bonding  Emeric Schultz
Students use toy connecting blocks and Velcro to investigate weak intermolecular interactions, specifically hydrogen bonds.
Schultz, Emeric. J. Chem. Educ. 2005, 82, 400A.
Noncovalent Interactions |
Hydrogen Bonding |
Phases / Phase Transitions / Diagrams |
Water / Water Chemistry |
Covalent Bonding |
Molecular Modeling |
Molecular Properties / Structure
Simple Dynamic Models for Hydrogen Bonding Using Velcro-Polarized Molecular Models  Emeric Schultz
This article describes the use of models that dynamically illustrate the unique characteristics of weak intermolecular interactions, specifically hydrogen bonds. The models clearly demonstrate that H-bonds can break and reform while covalent bonds stay intact. The manner in which the models form and break H-bonds reflects the geometric and statistical manner in which H-bonding actually occurs and is not contrived. The use of these models addresses a significant area of student misconceptions. The construction of these molecular models is described.
Schultz, Emeric. J. Chem. Educ. 2005, 82, 401.
Molecular Properties / Structure |
Molecular Modeling |
Noncovalent Interactions |
Hydrogen Bonding |
Water / Water Chemistry |
Phases / Phase Transitions / Diagrams
Three-Dimensional Model for Water: Magnets as Dipoles  Samuel H. Yalkowsky and Jennifer L. H. Johnson
Reply to comments on original article.
Yalkowsky, Samuel H.; Johnson, Jennifer L. H. J. Chem. Educ. 2004, 81, 34.
Aqueous Solution Chemistry |
Noncovalent Interactions |
Hydrogen Bonding |
Lipids |
Liquids |
Molecular Modeling |
Phases / Phase Transitions / Diagrams |
Solutions / Solvents |
Water / Water Chemistry
Three-Dimensional Model for Water: Magnets as Chemical Bonds  Roy W. Clark
Concerns over students confusing electrical and magnetic fields.
Clark, Roy W. J. Chem. Educ. 2004, 81, 34.
Aqueous Solution Chemistry |
Noncovalent Interactions |
Hydrogen Bonding |
Lipids |
Liquids |
Molecular Modeling |
Phases / Phase Transitions / Diagrams |
Solutions / Solvents |
Water / Water Chemistry
A Three-Dimensional Model for Water  J. L. H. Johnson and S. H. Yalkowsky
Using Molymod spheres and magnets to simulate the structure and properties of water and aqueous systems.
Johnson, J. L. H.; Yalkowsky, S. H. J. Chem. Educ. 2002, 79, 1088.
Aqueous Solution Chemistry |
Covalent Bonding |
Lipids |
Liquids |
Solutions / Solvents |
Water / Water Chemistry |
Phases / Phase Transitions / Diagrams
Liver and Onions: DNA Extraction from Animal and Plant Tissues  Karen J. Nordell, Anne-Marie L. Jackelen, S. Michael Condren, George C. Lisensky, and Arthur B. Ellis*
This activity, which allows students to extract DNA from plant and animal cells, serves as a spectacular example of the complexity of biochemical structure and function and fits well with a discussion of nucleic acids, hydrogen bonding, genetic coding, and heredity. DNA extraction can also be used in conjunction with a discussion of polymers and their properties.
Nordell, Karen J.; Jackelen, Anne-Marie L.; Condren, S. Michael; Lisensky, George C.; Ellis, Arthur B. J. Chem. Educ. 1999, 76, 400A.
Hydrogen Bonding |
Molecular Properties / Structure |
Nucleic Acids / DNA / RNA
Ammonia Can Crush  Ed Vitz
When a 12-oz aluminum soft drink can filled with ammonia or hydrogen chloride gas is inverted and dipped into water, the rapidly dissolving gas evacuates the can and the can is crushed before water can be drawn into it. This demonstrates, among other things, the remarkable strength of hydrogen bonds.
Vitz, Ed. J. Chem. Educ. 1999, 76, 932.
Noncovalent Interactions |
Gases |
Solutions / Solvents |
Hydrogen Bonding
Intermolecular Forces in Introductory Chemistry Studied by Gas Chromatography, Computer Models, and Viscometry  Jonathan C. Wedvik, Charity McManaman, Janet S. Anderson, and Mary K. Carroll
Students performing gas chromatographic (GC) analyses of mixtures of n-alkanes and samples that simulate crime scene evidence discover that liquid mixtures can be separated rapidly into their components based upon intermolecular forces. Each group of students is given a liquid sample that simulates one collected at an arson scene, and the group is required to determine the identity of the accelerant. Students also examine computer models to better visualize how molecular structure affects intermolecular forces: London forces, dipole-dipole interactions, and hydrogen bonding.
Wedvik, Jonathan C.; McManaman, Charity; Anderson, Janet S.; Carroll, Mary K. J. Chem. Educ. 1998, 75, 885.
Theoretical Chemistry |
Chromatography |
Noncovalent Interactions |
Gas Chromatography |
Molecular Modeling |
Forensic Chemistry |
Alkanes / Cycloalkanes |
Hydrogen Bonding |
Molecular Properties / Structure
Why Do Alcoholic Beverages Have "Legs"?  Todd P. Silverstein
After a sip of wine, "legs" of liquid typically run up and down the inside of the glass for many minutes. This phenomenon stems from the dipole-dipole intermolecular forces that are so important in understanding the physical behavior of aqueous solutions.
Silverstein, Todd P. J. Chem. Educ. 1998, 75, 723.
Noncovalent Interactions |
Aqueous Solution Chemistry |
Learning Theories |
Alcohols |
Hydrogen Bonding
The Real Reason Why Oil and Water Don't Mix  Todd P. Silverstein
Authors should remove from their textbooks the incorrect enthalpic/hydrogen-bond explanation for the hydrophobic effect. Because aspects of the correct entropic/clathrate "cage" explanation lie beyond the scope of introductory or organic chemistry courses, it may be wisest to omit any detailed physical explanation of the "like dissolves like" phenomenon.
Silverstein, Todd P. J. Chem. Educ. 1998, 75, 116.
Theoretical Chemistry |
Water / Water Chemistry |
Aqueous Solution Chemistry |
Solutions / Solvents
Can London Dispersion Forces Be Stronger than Dipole-Dipole Forces, Including Hydrogen Bonds?  Thomas T. Earles
Using French fries as an example in which London dispersion forces are stronger than dipole-dipole forces.
Earles, Thomas T. J. Chem. Educ. 1995, 72, 727.
Noncovalent Interactions |
Hydrogen Bonding
Why is water blue?  Braun, Charles L.; Smirnov, Sergei N.
Exploring the problem of why water in a beaker appears to be clear, yet we see large bodies of water as blue in color.
Braun, Charles L.; Smirnov, Sergei N. J. Chem. Educ. 1993, 70, 612.
Atomic Spectroscopy |
Water / Water Chemistry
Polarity, miscibility, and surface tension of liquids   Silverstein, Todd P.
A very simple overhead projector demonstration using water and ethanol to give a dramatic visual illustration of cohesive and adhesive forces.
Silverstein, Todd P. J. Chem. Educ. 1993, 70, 253.
Water / Water Chemistry |
Solutions / Solvents
Magic sand: Modeling the hydrophobic effect and reversed-phase liquid chromatography  Vitz, Ed
The procedures described here are meant to reveal the important "nonsolvent" properties of water through its interaction with Magic Sand, and other synthetic silica derivatives.
Vitz, Ed J. Chem. Educ. 1990, 67, 512.
Chromatography |
Water / Water Chemistry
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
Methane pistol  Skinner, James F.
This simple demonstration leaves a lasting impression of the importance of intermolecular forces and hydrogen bonding.
Skinner, James F. J. Chem. Educ. 1987, 64, 171.
Noncovalent Interactions |
Hydrogen Bonding |
Molecular Properties / Structure
A model for hydrogen bonding  Hill, John W.
Hydrogen bonding is a somewhat abstract and difficult concept for many students, yet it is of enormous importance in chemistry.
Hill, John W. J. Chem. Educ. 1986, 63, 503.
Hydrogen Bonding |
Noncovalent Interactions
Lemon meringue pie  Smith, Douglas D.
The chemistry and physics of lemon meringue pie.
Smith, Douglas D. J. Chem. Educ. 1982, 59, 60.
Gases |
Ionic Bonding |
Hydrogen Bonding |
Proteins / Peptides
Hydrogen bonding and heat of solution  Friedman, Norman
An experiment that clearly illustrates the role of hydrogen bond formation and its effect on the heat of solution.
Friedman, Norman J. Chem. Educ. 1977, 54, 248.
Hydrogen Bonding |
Calorimetry / Thermochemistry |
Solutions / Solvents
Non-covalent interactions: Key to biological flexibility and specificity  Frieden, Earl
Summarizes the types of non-covalent interactions found among biomolecules and how they facilitate the function of antibodies, hormones, and hemoglobin.
Frieden, Earl J. Chem. Educ. 1975, 52, 754.
Noncovalent Interactions |
Hydrogen Bonding |
Water / Water Chemistry |
Proteins / Peptides |
Amino Acids |
Molecular Properties / Structure |
Hormones
Using silica to demonstrate hydrogen bonding  Most, Clark, Jr.
The efficiency of a multitude of hydrogen bonds can be demonstrated by comparing the fluid character of mineral oil to the more solid character of the same oil to which has been added a small amount of finely divided silica.
Most, Clark, Jr. J. Chem. Educ. 1972, 49, 419.
Hydrogen Bonding |
Noncovalent Interactions
Is ammonia like water?  Gill, J. B.
This article sets out to compare some of the properties of the two most widely studied solvents, water and liquid ammonia, and in particular illustrate some comparative aspects that are not normally considered.
Gill, J. B. J. Chem. Educ. 1970, 47, 619.
Water / Water Chemistry |
Molecular Properties / Structure |
Aqueous Solution Chemistry
Atomic structure. Radioactivity (continued)   Alyea, Hubert N.
Formation of the complex Cu(NH3)4++ as an example of coordinate covalent bonding and hydrogen bonding as evidenced by viscosity.
Alyea, Hubert N. J. Chem. Educ. 1967, 44, A599.
Coordination Compounds |
Covalent Bonding |
Hydrogen Bonding |
Liquids
Lone pair electrons  Fowles, Gerald W. A.
The lone pair electrons, whether in simple or hybrid orbitals, have profound effects on the properties of the molecule; these effects may be discussed as bond angles, dipole moments, bond energies and lengths, and coordination and hydrogen bonding.
Fowles, Gerald W. A. J. Chem. Educ. 1957, 34, 187.
Atomic Properties / Structure |
Covalent Bonding |
Coordination Compounds |
Noncovalent Interactions |
Hydrogen Bonding |
Molecular Properties / Structure
Some aspects of hydrogen bonding in inorganic chemistry  Gorman, Mel
The purpose of this review is to present some of the research which is illustrative of the methods used and the results obtained with a variety of inorganic compounds in which hydrogen bonding is one of the structural features.
Gorman, Mel J. Chem. Educ. 1956, 33, 468.
Hydrogen Bonding |
Noncovalent Interactions