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Journal Articles: 62 results
A Simplified Synthetic Experiment of YBa2Cu3O7–x Superconductor for First-Year Chemistry Laboratory  Jui-Lin She and Ru-Shi Liu
In this first-year chemistry experiment, a simplified synthetic superconductor is prepared to demonstrate high temperature superconductivity and the Meissner effect.
She, Jui-Lin; Liu, Ru-Shi. J. Chem. Educ. 2008, 85, 825.
Materials Science |
Solid State Chemistry |
Superconductivity |
X-ray Crystallography
Preparation and Characterization of Solid Co(II) Pyrimidinolates in a Multifaceted Undergraduate Laboratory Experiment  Norberto Masciocchi, Simona Galli, Angelo Sironi, Gabriella Dal Monte, Elisa Barea, Juan Manuel Salas, and Jorge A. R. Navarro
Presents an integrated set of experiments involving the [Co(4-pyrimidinolate)2(H2O)n] species, including synthesis; analytical characterization by conventional titration and colorimetric methods; thermal, spectroscopic and structural characterization; and advanced analytical techniques (XRF, XRD).
Masciocchi, Norberto; Galli, Simona; Sironi, Angelo; Dal Monte, Gabriella; Barea, Elisa; Salas, Juan Manuel; Navarro, Jorge A. R. J. Chem. Educ. 2008, 85, 422.
Coordination Compounds |
Solid State Chemistry |
Synthesis |
Thermal Analysis |
X-ray Crystallography
Stuffed Derivatives of Close-Packed Structures  Bodie E. Douglas
Examines a variety of stuffed silica crystal structures in terms of the close-packing of one set of atoms or ions (P sites) with other atoms or ions in tetrahedral (T) or octahedral (O) sites and filled or partially filled layers in the regular pattern, PTOT.
Douglas, Bodie E. J. Chem. Educ. 2007, 84, 1846.
Crystals / Crystallography |
Group Theory / Symmetry |
Materials Science |
Metals |
Solid State Chemistry |
Solids
Modifying Optical Properties of ZnO Films by Forming Zn1-xCoxO Solid Solutions via Spray Pyrolysis  Anne K. Bentley, Gabriela C. Weaver, Cianán B. Russell, William L. Fornes, Kyoung-Shin Choi, and Susan M. Shih
Presents a simple experiment demonstrating the presence of an energy band gap in a semiconductor and its relationship to the material's composition through observed color and UVvis absorption.
Bentley, Anne K.; Weaver, Gabriela C.; Russell, Cianán B.; Fornes, William L.; Choi, Kyoung-Shin; Shih, Susan M. J. Chem. Educ. 2007, 84, 1183.
Materials Science |
Semiconductors |
Solid State Chemistry |
UV-Vis Spectroscopy
Titration of a Solid Acid Monitored By X-Ray Diffraction  Keenan E. Dungey and Paul Epstein
Presents a solid-state laboratory in which students react fixed amounts of zirconium phosphate with increasing equivalents of NaOH(aq). From X-ray diffraction patterns, students calculate the interplanar spacings before and after the reaction. The spacings increase until the molar equivalence point is reached, indicating incorporation of the sodium ion into the crystal.
Dungey, Keenan E.; Epstein, Paul. J. Chem. Educ. 2007, 84, 122.
Acids / Bases |
Crystals / Crystallography |
Materials Science |
Solid State Chemistry |
X-ray Crystallography |
Titration / Volumetric Analysis
Chemistry of Electronic Gases  James R. Clark
The chemistry of electronic gases can be used in the classroom to provide many interesting examples of molecular structures, chemical reactions, periodic trends, and environmental chemistry.
Clark, James R. J. Chem. Educ. 2006, 83, 857.
Applications of Chemistry |
Gases |
Industrial Chemistry |
Semiconductors |
Solid State Chemistry
Simultaneous Display of Spectral Images and Graphs Using a Web Camera and Fiber-Optic Spectrophotometer  Brian K. Niece
A method is presented for displaying images and graphs of spectra on a single screen in the classroom. The simultaneous display of both forms of the spectra helps students to make connections between the qualitative, visual spectra and quantitative, graphical representations.
Niece, Brian K. J. Chem. Educ. 2006, 83, 761.
Atomic Spectroscopy |
Solid State Chemistry |
UV-Vis Spectroscopy
Intelligent Thermochromic Windows  Ivan P. Parkin and Troy D. Manning
This article covers the background and related science associated with a thermochromic window, a device that changes its reflectance and transmission properties at a specific critical temperature.
Parkin, Ivan P.; Manning, Troy D. J. Chem. Educ. 2006, 83, 393.
Materials Science |
Physical Properties |
Solid State Chemistry
Self-Assembled Colloidal Crystals: Visualizing Atomic Crystal Chemistry Using Microscopic Analogues of Inorganic Solids  Neal M. Abrams and Raymond E. Schaak
Monodisperse spherical colloids spontaneously crystallize into close-packed crystals, in analogy to the simple crystal structures of many of the elements. Since colloids are orders of magnitude larger than atoms, students can directly observe crystal structure and behavior in a microscope using colloidal crystals. This laboratory exercise provides a modular series of materials science experiments appropriate for undergraduate chemistry and engineering majors. The individual modules include aspects of chemical synthesis (monodisperse SiO2 and polymer spheres), self-assembly (colloidal crystallization), and structural characterization through microscopy (optical and scanning electron microscopies) and optical spectroscopy (optical diffraction and UVvisible spectroscopy).
Abrams, Neal M.; Schaak, Raymond E. J. Chem. Educ. 2005, 82, 450.
Colloids |
Materials Science |
Solid State Chemistry |
Solids
Empirical Formulas and the Solid State: A Proposal  William B. Jensen
This brief article calls attention to the failure of most introductory textbooks to point out explicitly the fact that nonmolecular solids do not have molecular formulas and suggests some practical remedies for improving textbook coverage of this subject. The inadequacies of the terms "empirical formula" and "molecular formula" are also discussed, and the terms "relative compositional formula" and "absolute compositional formula" are proposed as more appropriate alternatives.
Jensen, William B. J. Chem. Educ. 2004, 81, 1772.
Solid State Chemistry |
Solids |
Stoichiometry |
Nomenclature / Units / Symbols
Using Organic Light-Emitting Electrochemical Thin-Film Devices To Teach Materials Science  Hannah Sevian, Sean Müller, Hartmut Rudmann, and Michael F. Rubner
Light-emitting thin films provide an excellent opportunity to learn about principles of electrochemistry, spectroscopy, microscopic structure of the solid state, basic circuits, and engineering design. There is currently strong interest in academic and industrial engineering research centering on developing organic light-emitting devices for applications in flat panel displays. In this educational module, designed for high school or introductory undergraduate courses, students learn how to make a ruthenium-based thin-film device. In the process, they learn about the solid-state electrochemistry at work in the film, as well as the electroluminescence that results when current passes through the device.
Sevian, Hannah; Müller, Sean; Rudmann, Hartmut; Rubner, Michael F. J. Chem. Educ. 2004, 81, 1620.
Electrochemistry |
Photochemistry |
Materials Science |
Oxidation / Reduction |
Solid State Chemistry
Spectacular Pseudo-Exfoliation of an Exfoliated–Compressed Graphite  M. Comet, L. Schreyeck, S. Verdan, G. Burato, and H. Fuzellier
This kind of reaction has been called pseudo-exfoliation of carbonaceous material. This demonstration spectacularly illustrates the layered nature of graphite.
Comet, M.; Schreyeck, L.; Verdan, S.; Burato, G.; Fuzellier, H. J. Chem. Educ. 2004, 81, 819.
Materials Science |
Oxidation / Reduction |
Solid State Chemistry
Inorganic Fullerenes, Onions, and Tubes  Andrew P. E. York
Proposed applications for the inorganic fullerenes include electronic devices and storage media, probes and electron microscope tips, and nano-ball bearings and high temperature lubricants.
York, Andrew P. E. J. Chem. Educ. 2004, 81, 673.
Materials Science |
Nanotechnology |
Solid State Chemistry
Dynamic Visualization in Chemistry Abstract of Special Issue 31, a CD-ROM for Mac OS and Windows  James P. Birk, Debra E. Leedy, Rachel A. Morgan, Mark Drake, Fiona Lihs, Eleisha J. Nickoles, and Michael J. McKelvy
Each presentation is designed to help chemistry students acquire a dynamic, three-dimensional, atomic-level visualization of matter and to use this view to explain and ultimately predict the behavior of materials. It integrates video of experiments and animations of theoretical models. Students zoom in on physical and chemical processes at resolutions as high as the atomic level.
Birk, James P.; Leedy, Debra E.; Morgan, Rachel A.; Drake, Mark; Lihs, Fiona; Nickoles, Eleisha J.; McKelvy, Michael J. J. Chem. Educ. 2003, 80, 1095.
Mechanisms of Reactions |
Solid State Chemistry
Paper-and-Glue Unit Cell Models  James P. Birk and Ellen J. Yezierski
Templates for a variety of unit cells that can be copied, cut out, and assembled.
Birk, James P.; Yezierski, Ellen J. J. Chem. Educ. 2003, 80, 157.
Solid State Chemistry |
Solids |
Crystals / Crystallography |
Molecular Modeling
Periodic Table Live! 3rd Edition: Abstract of Special Issue 17  Nicholas B. Adelman, Jon L. Holmes, Jerrold J. Jacobsen, John W. Moore, Paul F. Schatz, Jaclyn Tweedale, Alton J. Banks, John C. Kotz, William R. Robinson, and Susan Young
CD-ROM containing an interactive journey through the periodic table; includes information about each element, biographies of discoverers, videos of reactions, sources and uses, macro and atomic properties, and crystalline structures.
Adelman, Nicholas B.; Holmes, Jon L.; Jacobsen, Jerrold J.; Moore, John W.; Schatz, Paul F.; Tweedale, Jaclyn; Banks, Alton J.; Kotz, John C.; Robinson, William R.; Young, Susan. J. Chem. Educ. 2002, 79, 1487.
Descriptive Chemistry |
Periodicity / Periodic Table |
Solid State Chemistry |
Atomic Properties / Structure |
Physical Properties |
Reactions |
Crystals / Crystallography
Semiconductor Nanocrystals: A Powerful Visual Aid for Introducing the Particle in a Box  Tadd Kippeny, Laura A. Swafford, and Sandra J. Rosenthal
Using semiconductor nanocrystals as a means for connecting lecture content in quantum mechanics, inorganic, and general chemistry to real-world technological problems.
Kippeny, Tadd; Swafford, Laura A.; Rosenthal, Sandra J. J. Chem. Educ. 2002, 79, 1094.
Quantum Chemistry |
Nanotechnology |
Solid State Chemistry |
Crystal Field / Ligand Field Theory |
Applications of Chemistry
Semimetallicity?  Stephen J. Hawkes
Analysis of whether semimetals are semiconductors and distinctions between metals, semimetals, and nonmetals.
Hawkes, Stephen J. J. Chem. Educ. 2001, 78, 1686.
Atomic Properties / Structure |
Metals |
Periodicity / Periodic Table |
Nonmetals |
Physical Properties |
Solid State Chemistry |
Conductivity
LEDs Are Diodes  George C. Lisensky, S. Michael Condren, Cynthia G. Widstrand, Jonathan Breitzer, and Arthur B. Ellis
Comparison of incandescent bulbs with LEDs powered by AC and DC voltages; shows that LEDs are diodes and illustrates the relative energies of different wavelengths of light.
Lisensky, George C.; Condren, S. Michael; Widstrand, Cynthia G.; Breitzer, Jonathan; Ellis, Arthur B. J. Chem. Educ. 2001, 78, 1664A.
Atomic Properties / Structure |
Materials Science |
Nanotechnology |
Solid State Chemistry |
Applications of Chemistry
LEDs: New Lamps for Old and a Paradigm for Ongoing Curriculum Modernization  S. Michael Condren, George C. Lisensky, Arthur B. Ellis, Karen J. Nordell, Thomas F. Kuech, and Steve Stockman
Summary of the key points of a white paper on LEDs as potential replacements for a significant fraction of vehicle, display, home, and workplace lighting, with substantial safety and environmental conserving benefits.
Condren, S. Michael; Lisensky, George C.; Ellis, Arthur B.; Nordell, Karen J.; Kuech, Thomas F.; Stockman, Steve. J. Chem. Educ. 2001, 78, 1033.
Materials Science |
Nanotechnology |
Semiconductors |
Solid State Chemistry |
Applications of Chemistry
Glass Doesn't Flow and Doesn't Crystallize and It Isn't a Liquid  Stephen J. Hawkes
It is widely believed that glass flows in historic time and it is often asserted that glass is a liquid. The evidence of archeology, geology, and viscosity and of research on glass structure and on conservation of antique glass is examined and the conclusion in the title is reached. These fallacies should not be taught.
Hawkes, Stephen J. J. Chem. Educ. 2000, 77, 846.
Geochemistry |
Phases / Phase Transitions / Diagrams |
Solid State Chemistry
Experimental Demonstration of Isomorphism  J. Kamenícek and M. Melichárek
The effect of isomorphism may be demonstrated in two ways, using alums: by preparation of mixed crystals with various ratios of components, and by deposition of the second phase on the surface of the initial crystal. The experiments are described.
Kamencek, Jir; Melichrek, M. J. Chem. Educ. 2000, 77, 623.
Crystals / Crystallography |
Solid State Chemistry
Cubic Unit Cell Construction Kit  Bruce Mattson
This article provides plans for the construction of a student-interactive cubic unit cell model kit. Plans allow for the kit to be constructed on any scale. The kit is used in classroom activities or by students working alone or in small groups to construct the entire family of cubic lattices.
Mattson, Bruce. J. Chem. Educ. 2000, 77, 622.
Coordination Compounds |
Crystals / Crystallography |
Descriptive Chemistry |
Solid State Chemistry |
Molecular Modeling
Kixium Monolayers: A Simple Alternative to the Bubble Raft Model for Close-Packed Spheres  Keenan E. Dungey
This model focuses on the two-dimensional sheets, which are spontaneously formed from cereal pieces. The structure of the cereal rafts can be presented with an overhead projector.
Dungey, Keenan E. J. Chem. Educ. 2000, 77, 618.
Crystals / Crystallography |
Materials Science |
Solid State Chemistry
Sugar Dehydration without Sulfuric Acid: No More Choking Fumes in the Classroom!  Todd P. Silverstein and Yi Zhang
Our demonstration uses no sulfuric acid, yields relatively little smoke, and produces an exciting and unpredictable growing column of black carbon.
Silverstein, Todd P.; Zhang, Yi. J. Chem. Educ. 1998, 75, 748.
Carbohydrates |
Thermodynamics |
Electrochemistry |
Solid State Chemistry |
Oxidation / Reduction
Flying over Atoms CD-ROM: Abstract of Special Issue 19  John R. Markham
The 'Flying Over Atoms' software is a tool for teaching about atoms and solid surfaces in an introductory chemistry course.
Markham, John R. J. Chem. Educ. 1998, 75, 247.
Solid State Chemistry |
Surface Science
Solid State Structures (Abstract of Volume 5D, Number 2)  Ludwig A. Mayer
Solid State Structures is a collection of image files that allows the user to display, rotate, and examine individually a large collection of 3-D structure models.
Mayer, Ludwig A. J. Chem. Educ. 1997, 74, 1144.
Solid State Chemistry |
Metals |
Solids |
Molecular Properties / Structure |
Molecular Modeling
A Window on the Solid State: Part I: Structures of Metals; Part II: Unit Cells of Metals; Part III: Structures of Ionic Solids; Part IV: Unit Cells of Ionic Solids (Abstract of Volume 5D, Number 2)  William R. Robinson and Joan F. Tejchma
A Window on the Solid State helps students understand and instructors present the structural features of solids. The package provides a tour of the structures commonly used to introduce features of the solid state.
Robinson, William R.; Tejchma, Joan F. J. Chem. Educ. 1997, 74, 1143.
Solid State Chemistry |
Metals |
Solids |
Molecular Properties / Structure |
Molecular Modeling
Elements of Curriculum Reform: Putting Solids in the Foundation  Arthur B. Ellis
Until recently, solids were a relatively small part of the chemistry curriculum. Helping to close this particular gap between the research and educational enterprises was the objective of the Ad Hoc Committee for Solid-State Instructional Materials, formed in 1990.
Ellis, Arthur B. J. Chem. Educ. 1997, 74, 1033.
Materials Science |
Solid State Chemistry |
Nanotechnology |
Magnetic Properties
A Simple Laboratory Demonstration of Electrochromism  Bertil Forslund
A laboratory exercise in which students are asked to construct an electrochromic cell, consisting of a thin, transparent layer of WO3 on a glass plate with a thin, transparent, and conducting surface coating of doped SnO2.
Forslund, Bertil. J. Chem. Educ. 1997, 74, 962.
Electrochemistry |
Materials Science |
Solid State Chemistry
An Inexpensive Kit for Constructing Models of Crystals  Michael Laing
This simple kit comprises five trays, each of 25 square wells, and a lid. It can be used to construct primitive cubic, FCC, BCC, diamond, zinc blende, NaCl, CsCl, rutile, fluorite, perovskite structures. The trays are square tissue culture Petri dishes (multiwell plates). Atoms are represented by glass marbles.
Laing, Michael. J. Chem. Educ. 1997, 74, 795.
Crystals / Crystallography |
Materials Science |
Solid State Chemistry |
Molecular Properties / Structure
The Inorganic Illustrator: A 3-D Graphical Supplement for Inorganic and Bioinorganic Chemistry Courses Distributed on CD-ROM  Scott L. Childs and Karl S. Hagen
As part of this project we are accumulating a database of representative crystal structures of main group molecules, coordination complexes, organometallic compounds, small metalloproteins, bioinorganic model complexes, clusters, and solid state materials in Chem3D Plus format to be viewed with Chem3D Viewer, which is free software from Cambridge Scientific Computing.
Childs, Scott L.; Hagen, Karl S. J. Chem. Educ. 1996, 73, 917.
Molecular Modeling |
Enrichment / Review Materials |
Bioinorganic Chemistry |
Coordination Compounds |
Organometallics |
Main-Group Elements |
Solid State Chemistry
Solid State Resources CD  George C. Lisensky and Arthur B. Ellis
The Solid State Resource CD-ROM is intended to help instructors to integrate materials science examples into introductory chemistry courses.
Lisensky, G. C.; Ellis, A. B. . J. Chem. Educ. 1996, 73, 667.
Solid State Chemistry |
Materials Science
Surface Analysis by Scanning Tunneling Microscopy  Louis A. Coury, Jr, Mario Johnson, and Tammy J. Murphy
Project that involves using a scanning tunneling microscope to examine electrode surfaces before and after modification.
Coury, Jr., Louis A.; Johnson, Mario; Murphy, Tammy J. J. Chem. Educ. 1995, 72, 1088.
Surface Science |
Solid State Chemistry |
Nanotechnology
A Window on the Solid State  William R. Robinson and Christopher P. Saari
Student tutorial and lecture demonstration software illustrating the structures and unit cells of metals.
Robinson, W. R. . J. Chem. Educ. 1995, 72, 814.
Metals |
Crystals / Crystallography |
Solid State Chemistry
Rare Earth Iron Garnets: Their Synthesis and Magnetic Properties  Geselbracht, Margaret J.; Cappellari, Ann M.; Ellis, Arthur B.; Rzeznik, Maria A.; Johnson, Brian J.
A general synthesis for compositions in the solid solution series YxGd3-xFe5O12 (x = 0, 1, 2, 3) and a simple demonstration that illustrates the differing magnetic properties of these materials.
Geselbracht, Margaret J.; Cappellari, Ann M.; Ellis, Arthur B.; Rzeznik, Maria A.; Johnson, Brian J. J. Chem. Educ. 1994, 71, 696.
Metals |
Transition Elements |
Magnetic Properties |
Synthesis |
Solid State Chemistry
Solid State Structures for MacMolecule  Mayer, Ludwig A.
Provides an effective visualization of extended structure solids.
Mayer, Ludwig A. J. Chem. Educ. 1994, 71, 421.
Solid State Chemistry |
Solids |
Molecular Modeling |
Molecular Properties / Structure
Nickel-Titanium Memory Metal: A "Smart" Material Exhibiting a Solid-State Phase Change and Superelasticity  Gisser, Kathleen R. C.; Geselbracht, Margaret J.; Cappellari, Ann; Hunsberger, Lynn; Ellis, Arthur B.; Perepezko, John; Lisensky, George C.
Several simple experiments that illustrate the shape-memory, mechanical, and acoustical properties of Nitinol.
Gisser, Kathleen R. C.; Geselbracht, Margaret J.; Cappellari, Ann; Hunsberger, Lynn; Ellis, Arthur B.; Perepezko, John; Lisensky, George C. J. Chem. Educ. 1994, 71, 334.
Solid State Chemistry |
Phases / Phase Transitions / Diagrams |
Materials Science |
Applications of Chemistry
A Window on the Solid-State  Robinson, William R.
"Part I: Structures of Metals" introduces the four basic structural types found in metals. "Part II: Unit Cells of Metals" discusses how to use a unit cell to describe a two-dimensional structure.
Robinson, William R. J. Chem. Educ. 1994, 71, 300.
Solid State Chemistry |
Solids |
Metals
Solid state chemistry: Taught as a comprehensive university course for chemistry students  Boldyreva, Elena V.
While the importance of solid state chemistry for both fundamental chemical science and for modern technology is recognized, there are hardly any comprehensive courses offered for non-specialist students. This author relates her experience in offering such a course.
Boldyreva, Elena V. J. Chem. Educ. 1993, 70, 551.
Solid State Chemistry |
Materials Science
A simple and reliable chemical preparation of YBa2Cu3O7-x superconductors: An experiment in high temperature superconductivity for an advanced undergraduate laboratory  Djurovich, Peter I.; Watts, Richard J.
The popular kits used to engage students in sythetic procedures contain pedagogical flaws. This article presents an alternative to the so-called "shake and bake" kits.
Djurovich, Peter I.; Watts, Richard J. J. Chem. Educ. 1993, 70, 497.
Semiconductors |
Materials Science |
Solid State Chemistry |
Superconductivity
The importance of understanding structure   Galasso, Frank
Solid state chemistry and its link with atomic structure is a topic that is still being neglected in students' education., despite the interesting scientific discoveries and developments that will likely be relevant in students' lives and possible careers.
Galasso, Frank J. Chem. Educ. 1993, 70, 287.
Solid State Chemistry |
Materials Science |
Solids |
Physical Properties
Conducting midshipmen - A classroom activity modeling extended bonding in solids  Lomax, Joseph F.
Using the electron-hopping model (analogous to people sitting in chairs) to explain electron movement and conductivity in insulators, semiconductors, and metals.
Lomax, Joseph F. J. Chem. Educ. 1992, 69, 794.
Solids |
Solid State Chemistry |
Conductivity |
Metals |
Semiconductors
Diffraction of a laser light by a memory chip   Klier, Kamil; Taylor, J. Ashley
A way of demonstrating the relationship between structure and diffraction.
Klier, Kamil; Taylor, J. Ashley J. Chem. Educ. 1991, 68, 155.
X-ray Crystallography |
Solids |
Solid State Chemistry |
Surface Science |
Materials Science
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
The squeezed-earth problem   Rhodes, Gale
This take-home-exam question promotes a discussion in class and demonstrates the conceptual difficulties in understanding protons and neutrons.
Rhodes, Gale J. Chem. Educ. 1986, 63, 970.
Atomic Properties / Structure |
Solid State Chemistry
Crystal model kits for use in the general chemistry laboratory  Kildahl, Nicholas K.; Berka, Ladislav, H.; Bodner, George M.
This paper describes dynamic crystal models which were developed independently at the Worcester Polytech institute and Purdue University.
Kildahl, Nicholas K.; Berka, Ladislav, H.; Bodner, George M. J. Chem. Educ. 1986, 63, 62.
Crystals / Crystallography |
Solids |
Solid State Chemistry
Inorganic thermochromism: A lecture demonstration of a solid state phase transition  Willett, Roger D.
A description of an activity using thermochromic material is an easy way to demonstrate solid state phase transition.
Willett, Roger D. J. Chem. Educ. 1983, 60, 355.
Phases / Phase Transitions / Diagrams |
Solid State Chemistry |
Coordination Compounds
The barium hydroxide ammonium thiocyanate reaction: A titrimetric continuous variations experiment  Harris, Arlo D.
Experiment that uses acid-base titrimetry to study the stoichiometry of a novel solid state reaction.
Harris, Arlo D. J. Chem. Educ. 1979, 56, 477.
Titration / Volumetric Analysis |
Acids / Bases |
Solid State Chemistry |
Stoichiometry
A simple and inexpensive solar energy experiment  Evans, J. H.; Pedersen, L. G.
Uses solid state technology to demonstrate the direct generation of electricity and the electrochemical generation of hydrogen.
Evans, J. H.; Pedersen, L. G. J. Chem. Educ. 1979, 56, 339.
Solid State Chemistry |
Semiconductors |
Electrochemistry
Solar energy  J. Chem. Educ. Staff
Information summarizing a variety of topics related to solar energy.
J. Chem. Educ. Staff J. Chem. Educ. 1979, 56, 264.
Applications of Chemistry |
Solid State Chemistry |
Semiconductors
A demonstration in solid state chemistry: The nonstoichiometry of nickel oxide, NiO  Perrino, Charles T.; Johnson, Robert
A simple experiment to demonstrate the nonstoichiometric synthesis of nickel oxide.
Perrino, Charles T.; Johnson, Robert J. Chem. Educ. 1977, 54, 367.
Stoichiometry |
Oxidation State |
Oxidation / Reduction |
Solid State Chemistry |
Metals
Chemical symbolism and the solid state. A proposal  Jensen, William B.
A proposed symbolism for representing the solid state.
Jensen, William B. J. Chem. Educ. 1977, 54, 277.
Solid State Chemistry |
Crystals / Crystallography
Freshman-level chemistry shapes the nuclear power industry  Plumb, Robert C.; Bridgman, W. B.; Wilbur, Leslie C.
Applying the modeling of a crystalline lattice to the changes occurring in a nuclear reactor.
Plumb, Robert C.; Bridgman, W. B.; Wilbur, Leslie C. J. Chem. Educ. 1975, 52, 523.
Crystals / Crystallography |
Molecular Modeling |
Solids |
Solid State Chemistry |
Nuclear / Radiochemistry |
Applications of Chemistry
Solid state labs: The bubble raft  McCormick, P. D.
Method for producing bubble rafts and experiments for using them to demonstrate the properties of crystals.
McCormick, P. D. J. Chem. Educ. 1975, 52, 521.
Solids |
Solid State Chemistry |
Crystals / Crystallography
An inexpensive method to produce plastic models of solids  Salmon, J. F. S. J.; Polley, C. A.
Method for using moulage to produce plastic models of solids.
Salmon, J. F. S. J.; Polley, C. A. J. Chem. Educ. 1973, 50, 726.
Solids |
Molecular Modeling |
Solid State Chemistry
Diphenyl ether. A versatile substance for laboratory demonstrations  Cases, Jaime C.
The purification, properties, and uses of diphenyl ether in a variety of demonstrations.
Cases, Jaime C. J. Chem. Educ. 1973, 50, 420.
Ethers |
Solid State Chemistry |
Physical Properties |
Aromatic Compounds
Free energies of formation measurements on solid-state electrochemical cells  Rollino, J. A.; Aronson, S.
This experiment demonstrates in a direct fashion the relationship between the Gibbs free energy of formation of an ionic solid and the emf of an electrochemical cell.
Rollino, J. A.; Aronson, S. J. Chem. Educ. 1972, 49, 825.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Solid State Chemistry |
Organometallics
An introduction to principles of the solid state. Extrinsic semiconductors  Weller, Paul F.
Includes a previous analogy is extended to cover n- and p-type semiconductors and discussions of the concepts of donors and acceptors, donor and acceptor activation energies and the corresponding charge carrier production at various temperatures, and the effects of the presence of both donors and acceptors.
Weller, Paul F. J. Chem. Educ. 1971, 48, 831.
Solid State Chemistry |
Solids |
Semiconductors
An analogy for elementary band theory concepts in solids  Weller, Paul F.
The author presents analogies to help students understand insulators and metals, semiconductors, and the p-n junction.
Weller, Paul F. J. Chem. Educ. 1967, 44, 391.
Semiconductors |
Solid State Chemistry |
Metals
An analogy for the band theory of metals  van Reuth, E. C.
Presents a useful analogy for teaching students the band theory of metals.
van Reuth, E. C. J. Chem. Educ. 1966, 43, 484.
Metals |
Solid State Chemistry |
Semiconductors
Standard ionic crystal structures  Gehman, William G.
Examines the topics of cubic and hexagonal closest packed atom lattices; interstice lattices; standard crystal structures of type MaXb; standard CCP and HCP crystal structures; and deviations from ideal closest packing.
Gehman, William G. J. Chem. Educ. 1963, 40, 54.
Crystals / Crystallography |
Solids |
Molecular Modeling |
Solid State Chemistry