TIGER

Journal Articles: 101 results
New Observations on the Copper-to-Silver-to-Gold Demonstration  Dorin Bejan, Jeff Hastie, and Nigel J. Bunce
This analysis of the classic copper-to-silver-to-gold demonstration describes the deposition of zinc in the form of the silver-colored alloy ?-brass, the evolution of hydrogen at the copper cathode, and the behavior of the associated electrochemical cell.
Bejan, Dorin; Hastie, Jeff; Bunce, Nigel J. J. Chem. Educ. 2008, 85, 1381.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Oxidation State |
Oxidation / Reduction
Introducing Undergraduate Students to Electrochemistry: A Two-Week Discovery Chemistry Experiment  Kenneth V. Mills, Richard S. Herrick, Louise W. Guilmette, Lisa P. Nestor, Heather Shafer, and Mauri A. Ditzler,
Within the framework of a laboratory-focused, guided-inquiry pedagogy, students discover the Nernst equation, the spontaneity of galvanic cells, concentration cells, and the use of electrochemical data to calculate equilibrium constants.
Mills, Kenneth V.; Herrick, Richard S.; Guilmette, Louise W.; Nestor, Lisa P.; Shafer, Heather;Ditzler, Mauri A. J. Chem. Educ. 2008, 85, 1116.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Equilibrium
Yet Another Variation on the Electrolysis of Water at Iron Nails  Mark T. Stauffer and Justin P. Fox
Describes a variation on the electrolysis of water with iron nails in which a sharp contrast in the colors produced effectively demonstrates electrolysis and the diffusion of oxidized and reduced species from the electrodes.
Stauffer, Mark T.; Fox, Justin P. J. Chem. Educ. 2008, 85, 523.
Acids / Bases |
Electrochemistry |
Oxidation / Reduction |
Stoichiometry |
Water / Water Chemistry |
Electrolytic / Galvanic Cells / Potentials
Demonstration Extensions: Flame Tests and Electrolysis  Ed Vitz
Provides suggestions to supplement traditional demonstrations involving flame tests and water hydrolysis.
Vitz, Ed. J. Chem. Educ. 2008, 85, 522.
Alcohols |
Electrolytic / Galvanic Cells / Potentials
Electrochemical Polishing of Silverware: A Demonstration of Voltaic and Galvanic Cells  Michelle M. Ivey and Eugene T. Smith
Using a battery and a graphite electrode, an electrolytic cell is constructed to generate a layer of tarnish on silverware. Students then determine that the tarnish can be removed by electrochemically converting it back to silver using aluminum foil and baking soda.
Ivey, Michelle M.; Smith, Eugene T. J. Chem. Educ. 2008, 85, 68.
Consumer Chemistry |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
The Use of Conjugate Charts in Transfer Reactions: A Unified Approach  Michael I. Allnutt
Redox reactions are discussed in terms of the relative strengths of the oxidant, the reductant, and their conjugates; a conjugate chart is a convenient and useful way of doing this. A similar chart for acids and bases that can be applied in the same manner is proposed.
Allnutt, Michael I. J. Chem. Educ. 2007, 84, 1659.
Acids / Bases |
Electrolytic / Galvanic Cells / Potentials |
Oxidation / Reduction |
Brønsted-Lowry Acids / Bases
Textbook Error: Short Circuiting an Electrochemical Cell  Judith M. Bonicamp and Roy W. Clark
Reports a serious error in the electrochemical diagrams in eight, 21st century texts and offers an analogy to electrical potential energy and a diagram to clarify the interrelationships between electromotive force E, reaction quotient Q, and Gibbs free energy G.
Bonicamp, Judith M.; Clark, Roy W. J. Chem. Educ. 2007, 84, 731.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Exploring Faraday's Law of Electrolysis Using Zinc–Air Batteries with Current Regulative Diodes  Masahiro Kamata and Miei Paku
Describes a new educational experiment using low-cost zincair batteries and current regulative diode arrays to quickly confirm Faraday's law of electrolysis.
Kamata, Masahiro; Paku, Miei. J. Chem. Educ. 2007, 84, 674.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Laboratory Equipment / Apparatus |
Oxidation / Reduction
Small-Scale and Low-Cost Electrodes for "Standard" Reduction Potential Measurements  Per-Odd Eggen, Lise Kvittingen, and Truls Grønneberg
This article describes how to construct three simple and inexpensive, microchemistry electrodes: hydrogen, chlorine, and copper.
Eggen, Per-Odd; Grønneberg, Truls; Kvittingen, Lise. J. Chem. Educ. 2007, 84, 671.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Laboratory Equipment / Apparatus |
Microscale Lab |
Student-Centered Learning
A Lemon Cell Battery for High-Power Applications  Kenneth R. Muske, Christopher W. Nigh, and Randy D. Weinstein
This article discusses the development of a lemon cell battery for high-power applications such as radios, portable cassette or CD players, and battery-powered toys.
Muske, Kenneth R.; Nigh, Christopher W.; Weinstein, Randy D. J. Chem. Educ. 2007, 84, 635.
Applications of Chemistry |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Laboratory Experiments on the Electrochemical Remediation of the Environment. Part 7: Microscale Production of Ozone  Jorge G. Ibanez, Rodrigo Mayen-Mondragon, M. T. Moran-Moran, Alejandro Alatorre-Ordaz, Bruce Mattson, and Scot Eskestrand
Ozone, a powerful oxidizing and disinfecting agent, is produced electrochemically in the undergraduate laboratory with simple equipment and under very mild conditions. Tests are given to characterize it, to observe its action in simulated environmental applications, and to measure its rate of production.
Ibanez, Jorge G.; Mayen-Mondragon, Rodrigo; Moran-Moran, M. T.; Alatorre-Ordaz, Alejandro; Mattson, Bruce; Eskestrand, Scot. J. Chem. Educ. 2005, 82, 1546.
Aqueous Solution Chemistry |
Descriptive Chemistry |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Laboratory Equipment / Apparatus |
Microscale Lab |
Oxidation / Reduction |
Reactions
Conceptual Considerations in Molecular Science  Donald T. Sawyer
The undergraduate curriculum and associated textbooks include several significant misconceptions.
Sawyer, Donald T. J. Chem. Educ. 2005, 82, 985.
Catalysis |
Covalent Bonding |
Electrolytic / Galvanic Cells / Potentials |
Oxidation / Reduction |
Reactions |
Reactive Intermediates |
Thermodynamics |
Water / Water Chemistry
The Effective Use of an Interactive Software Program To Reduce Students' Misconceptions about Batteries  E.-M. Yang, T. J. Greenbowe, and T. Andre
In this study, college students enrolled in an introductory chemistry course were asked a series of open-ended questions about electrochemistry, flashlights, and batteries. Misconceptions were identified, analyzed, and used to develop and test an Interactive Software Program (ISP).
Yang, E.-M.; Greenbowe, T. J.; Andre, T. J. Chem. Educ. 2004, 81, 587.
Electrochemistry |
Learning Theories |
Electrolytic / Galvanic Cells / Potentials |
Student-Centered Learning
Photogalvanic Cells for Classroom Investigations: A Contribution for Ongoing Curriculum Modernization  Claudia Bohrmann-Linde and Michael W. Tausch
Laboratory experiments examining the fundamental processes in the conversion of light into electrical energy using photogalvanic cells have been developed. These simple cells are suitable for classroom investigations examining the operating principles of photogalvanic cells and the influence of different parameters on their efficiency.
Bohrmann-Linde, Claudia; Tausch, Michael W. J. Chem. Educ. 2003, 80, 1471.
Electrochemistry |
Atomic Properties / Structure |
Photochemistry |
Oxidation / Reduction |
Electrolytic / Galvanic Cells / Potentials
Lithium Batteries: A Practical Application of Chemical Principles  Richard S. Treptow
In recent years batteries have emerged in the marketplace that take advantage of the unique properties of lithium. Lithium metal is an attractive choice to serve as a battery anode because it is easily oxidized and it produces an exceptionally high amount of electrical charge per unit-weight.
Treptow, Richard S. J. Chem. Educ. 2003, 80, 1015.
Consumer Chemistry |
Electrochemistry |
Oxidation / Reduction |
Electrolytic / Galvanic Cells / Potentials |
Applications of Chemistry
Lithium Batteries: A Practical Application of Chemical Principles  Richard S. Treptow
In recent years batteries have emerged in the marketplace that take advantage of the unique properties of lithium. Lithium metal is an attractive choice to serve as a battery anode because it is easily oxidized and it produces an exceptionally high amount of electrical charge per unit-weight.
Treptow, Richard S. J. Chem. Educ. 2003, 80, 1015.
Consumer Chemistry |
Electrochemistry |
Oxidation / Reduction |
Electrolytic / Galvanic Cells / Potentials |
Applications of Chemistry
Why Do Some Batteries Last Longer Than Others?  Michael J. Smith and Colin A. Vincent
Comparing the energy content of the cathode material of different commercial batteries using a test cell.
Smith, Michael J.; Vincent, Colin A. J. Chem. Educ. 2002, 79, 851.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Applications of Chemistry
A Direct Methanol Fuel Cell  Orfeo Zerbinati
Materials and methods for construction of a direct methanol fuel cell.
Zerbinati, Orfeo. J. Chem. Educ. 2002, 79, 829.
Electrochemistry |
Laboratory Equipment / Apparatus |
Electrolytic / Galvanic Cells / Potentials
Conceptual Difficulties Experienced by Prospective Teachers in Electrochemistry: Half-Cell Potential, Cell Potential, and Chemical and Electrochemical Equilibrium in Galvanic Cells  Ali Riza Özkaya
Study of prospective teachers' conceptual understanding of topics in electrochemistry.
Özkaya, Ali Riza. J. Chem. Educ. 2002, 79, 735.
Electrochemistry |
Equilibrium |
Electrolytic / Galvanic Cells / Potentials
The Lead-Acid Battery: Its Voltage in Theory and in Practice  Richard S. Treptow
Lead-acid battery fundamentals, cell voltage and the Nernst equation, and an analysis of actual battery performance.
Treptow, Richard S. J. Chem. Educ. 2002, 79, 334.
Electrochemistry |
Oxidation / Reduction |
Thermodynamics |
Electrolytic / Galvanic Cells / Potentials |
Acids / Bases |
Applications of Chemistry
Structure and Content of Some Primary Batteries  Michael J. Smith and Colin A. Vincent
An experiment that complements electrochemical characterization and allows students to explore the structure of commercial cells and calculate the anode and cathode capacities from the stoichiometry of the cell reaction.
Smith, Michael J.; Vincent, Colin A. J. Chem. Educ. 2001, 78, 519.
Consumer Chemistry |
Electrochemistry |
Undergraduate Research |
Electrolytic / Galvanic Cells / Potentials |
Applications of Chemistry
Observations on Lemon Cells  Jerry Goodisman
The lemon cell, consisting of pieces of two different metals stuck into a lemon or other fruit, is pictured in many general chemistry textbooks without being discussed; manuscript describes simple experiments, suitable for the general chemistry laboratory, which elucidate how this kind of cell works.
Goodisman, Jerry. J. Chem. Educ. 2001, 78, 516.
Electrochemistry |
Metals |
Electrolytic / Galvanic Cells / Potentials
Understanding Electrochemical Thermodynamics through Entropy Analysis  Thomas H. Bindel
This discovery-based activity involves entropy analysis of galvanic cells. The intent of the activity is for students to discover the fundamentals of electrochemical cells through a combination of entropy analysis, exploration, and guided discovery.
Bindel, Thomas H. J. Chem. Educ. 2000, 77, 1031.
Electrochemistry |
Thermodynamics |
Electrolytic / Galvanic Cells / Potentials
Lemon Cells Revisited  Radhakrishnamurty, P.
Analysis of the reactions and nature of the electrodes in the lemon cell.
Radhakrishnamurty, P. J. Chem. Educ. 1999, 76, 1190.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Oxidation / Reduction
Slide Projector Corrosion Cell  Silvia Tejada, Estela Guevara, and Esperanza Olivares
The process of corrosion can be demonstrated in a slide projector, since the cell is in the shape of a slide, or on the stage of an overhead projector by setting up a simple galvanic cell. Corrosion occurs as the result of a galvanic cell reaction, in which the corroding metal acts as the anode. Several simple demonstrations relating to corrosion are described here.
Tejada, Silvia; Guevara, Estela; Olivares, Esperanza. J. Chem. Educ. 1998, 75, 747.
Electrochemistry |
Microscale Lab |
Oxidation / Reduction |
Reactions |
Electrolytic / Galvanic Cells / Potentials |
Applications of Chemistry
Lemon Cells Revisited - The Lemon-Powered Calculator  Daniel J. Swartling and Charlotte Morgan
Using lemons to create a voltaic cell to run items that students would use in their everyday lives drives home that chemistry plays an integral role in their lives.
Swartling, Daniel J.; Morgan, Charlotte. J. Chem. Educ. 1998, 75, 181.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Applications of Chemistry
Students' Misconceptions in Electrochemistry Regarding Current Flow in Electrolyte Solutions and the Salt Bridge  Michael J. Sanger and Thomas J. Greenbowe
Several researchers have documented students' misconceptions in electrochemistry. One reason for the interest in studying electrochemistry is that surveys of students and teachers suggest that students find this topic difficult and research confirms that students' beliefs about problem complexity affect their performance and learning.
Sanger, Michael J.; Greenbowe, Thomas J. J. Chem. Educ. 1997, 74, 819.
Learning Theories |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Aqueous Solution Chemistry
Small Scale Electrolytic Cells  Anderson, Guy E.
A method is given for a quantitative electrolysis experiment that does not require specialized equipment.
Anderson, Guy E. J. Chem. Educ. 1996, 73, A172.
Electrolytic / Galvanic Cells / Potentials |
Microscale Lab |
Quantitative Analysis |
Electrochemistry
Voltaic Cell Measurements on a Spot Plate with a Cotton Swab Salt Bridge  Dobrzynski, Edward D.
Microscale voltaic cell measurements using very small solution volumes are carried out on a porcelain spot plate. A suitable salt bridge is constructed by filling the hollow plastic tube of a double-tipped cotton swab with an electrolyte gel mixture.
Dobrzynski, Edward D. J. Chem. Educ. 1996, 73, A6.
Microscale Lab |
Electrolytic / Galvanic Cells / Potentials
Electrode Processes and Aspects Relating to Cell EMF, Current, and Cell Components in Operating Electrochemical Cells: Precollege and College Student Interpretation  N. A. Ogude and J. D. Bradleu
Four areas that present difficulty among high school pupils and tertiary level students in relation to the processes that take place in operating electrochemical cells were identified, including conduction in the electrolyte, electrical neutrality, electrode processes and terminology, and aspects relating to cell emf, current, and cell components. A 20-item questionnaire was designed to determine how widespread misconceptions in these areas were.
Ogude, N. A.; Bradley, J. D. J. Chem. Educ. 1996, 73, 1145.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
A Simple Method for Determining the Temperature Coefficient of Voltaic Cell Voltage  Alfred E. Saieed, Keith M. Davies
This article describes a relatively simple method for preparing voltaic cells, and through their temperature coefficient, ?E/?T, it explores relationships between ?G, ?H,and ?S for the cell reactions involved.
Saieed, Alfred E.; Davies, Keith M. J. Chem. Educ. 1996, 73, 959.
Electrochemistry |
Calorimetry / Thermochemistry |
Thermodynamics |
Electrolytic / Galvanic Cells / Potentials |
Laboratory Equipment / Apparatus |
Laboratory Management |
Oxidation / Reduction
The Comparative Performance of Batteries: The Lead-Acid and the Aluminum-Air Cells  Xavier LeRoux, Gerry A. Ottewill, and Frank C. Walsh
An experimental program designed to convey, to students aged 16 through undergraduate, the principles of battery electrochemistry through a comparative study of two different systems, the lead acid cell and aluminum air cell, is described.
LeRoux, Xavier; Ottewill, Gerry A.; Walsh, Frank C. J. Chem. Educ. 1996, 73, 811.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Applications of Chemistry
Demonstration of the Plasma State  Joachim P. Schreckenbach and Klaus Rabending
Important basic properties of the plasma state are recognized in a simple experimental arrangement described in this article.
Schreckenbach, Joachim P.; Rabending, Klaus. J. Chem. Educ. 1996, 73, 782.
Phases / Phase Transitions / Diagrams |
Conductivity |
Electrolytic / Galvanic Cells / Potentials
Work Done by a Chemical Reaction  Henry Brouwer
The use of the "hot dog clock" has been the focus of discussions in a number of areas of electrochemistry. Included in these have been oxidation-reduction potentials, battery construction, salt bridges, electrolytes, and the concentration of ions in certain foods.
Brouwer, Henry. J. Chem. Educ. 1996, 73, 354.
Electrochemistry |
Food Science |
Oxidation / Reduction |
Electrolytic / Galvanic Cells / Potentials
The "Golden Penny" Demonstration: An Explanation of the Old Experiment and the Rational Design of the New and Simpler Demonstration.  Szczepankiewicz, Steven H.; Bieron, Joseph F.; Kozik, Mariusz
An explanation and simpler/safer design for the classical "gold penny" demonstration.
Szczepankiewicz, Steven H.; Bieron, Joseph F.; Kozik, Mariusz J. Chem. Educ. 1995, 72, 386.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Use of Electrochemical Concentration Cells to Demonstrate the Dimeric Nature of Mercury(I) in Aqueous Media  Bhattacharya, Deepta; Peters, Dennis G.
Experimental procedure for demonstrating that divalent mercury is monovalent in aqueous solution; includes data and analysis.
Bhattacharya, Deepta; Peters, Dennis G. J. Chem. Educ. 1995, 72, 64.
Atomic Properties / Structure |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Aqueous Solution Chemistry
Augmenting a classical electrochemical demonstration  Yochum, Susan M.; Luoma, John R.
Substituting magnesium for zinc in the copper/zinc electrochemical cell to enhance student understanding of electrochemistry; includes data and analysis.
Yochum, Susan M.; Luoma, John R. J. Chem. Educ. 1995, 72, 55.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Simulations and Interactive Resources  Martin, John S.
12 Simulations and Interactive Resources (SIRs) including Periodic Table Displays, Electron Orbits and Orbitals, Electron Configurations, Barometers and Manometers, Vapor Pressure, Ideal Gas Behavior, Heat Capacity and Heat of Reaction, Approach to Equilibrium, The Law of Chemical Equilibrium, Titration Curves, Electrochemical Cells, and Rate of Reaction.
Martin, John S. J. Chem. Educ. 1994, 71, 667.
Periodicity / Periodic Table |
Atomic Properties / Structure |
Gases |
Calorimetry / Thermochemistry |
Equilibrium |
Titration / Volumetric Analysis |
Electrolytic / Galvanic Cells / Potentials |
Rate Law
An Interactive Multimedia Software Program for Exploring Electrochemical Cells  Greenbowe, Thomas J.
The "Electrochemical Workbench" is one component of a software package that allows students and faculty to explore building and testing electrochemical cells by simulating a chemistry laboratory in which students can perform experiments.
Greenbowe, Thomas J. J. Chem. Educ. 1994, 71, 555.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Aqueous Solution Chemistry
Using the Biological Cell in Teaching Electrochemistry  Merkel, Eva Gankiewicz
How electricity is produced in a simple cell is correlated with how commercial batteries work; this concept can then be related to how living cells send electrical impulses.
Merkel, Eva Gankiewicz J. Chem. Educ. 1994, 71, 240.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Equilibrium
Ionic Conduction and Electrical Neutrality in Operating Electrochemical Cells: Pre-College and College Student Interpretations  Ogude, A. N.; Bradley, J. D.
Results of an investigation on pre-college and college student difficulties regarding the qualitative interpretation of the microscopic processes that take place in operating chemical cells.
Ogude, A. N.; Bradley, J. D. J. Chem. Educ. 1994, 71, 29.
Conductivity |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Chemical Demonstrations: A Handbook for Teachers of Chemistry, Volume 4 (Shakhashiri, Bassam Z.)  Kauffman, George B.
78 procedures grouped into two chapters, one on clock reactions, the other on electrochemistry, batteries, electrolytic cells, and plating.
Kauffman, George B. J. Chem. Educ. 1992, 69, A187.
Reactions |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
The anode and the sunrise.  Mierzecki, Roman.
Etymology of the terms anode and cathode.
Mierzecki, Roman. J. Chem. Educ. 1992, 69, 657.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Nomenclature / Units / Symbols
The world's largest human salt bridge  Silverman, L. Phillip; Bunn, Barbara B.
On a beautiful April afternoon, the 1500 students had fun and learned something about electrochemistry, and they helped set a world's record for the "Longest Human Salt Bridge".
Silverman, L. Phillip; Bunn, Barbara B. J. Chem. Educ. 1992, 69, 309.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
The Voltaic pile: A stimulating general chemistry experiment   Scharlin, Pirketta; Battino, Rubin
An inexpensive, simple, and fun way to illustrate many of the principles in electrochemistry.
Scharlin, Pirketta; Battino, Rubin J. Chem. Educ. 1991, 68, 665.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Half cell reactions: Do students ever see them?   Ciparick, Joseph D.
This demonstration shows more clearly that there are two real half reactions.
Ciparick, Joseph D. J. Chem. Educ. 1991, 68, 247.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Electrochemical conventions: Responses to a provocative opinion (6)  Martin-Sanchez, M.; Martin-Sanchez, MaT
The solution may be to use the etymological meaning of anode and cathode.
Martin-Sanchez, M.; Martin-Sanchez, MaT J. Chem. Educ. 1990, 67, 992.
Electrochemistry |
Nomenclature / Units / Symbols |
Electrolytic / Galvanic Cells / Potentials
Electrochemical conventions: Responses to a provocative opinion (5)  Sweeting, Linda M.
The chemical potential of the electrons, not their "richness" determines direction of flow.
Sweeting, Linda M. J. Chem. Educ. 1990, 67, 992.
Electrochemistry |
Nomenclature / Units / Symbols |
Electrolytic / Galvanic Cells / Potentials
Electrochemical conventions: Responses to a provocative opinion (4)  Fochi, Giovanni
It is sufficient to show what part of the circuit is the electric generator.
Fochi, Giovanni J. Chem. Educ. 1990, 67, 992.
Electrochemistry |
Nomenclature / Units / Symbols |
Electrolytic / Galvanic Cells / Potentials
Electrochemical conventions: Responses to a provocative opinion (3)  Woolf, A. A.
There are no shortcuts in teaching the electrochemistry of galvanic cells; the process in each cell must be treated holistically.
Woolf, A. A. J. Chem. Educ. 1990, 67, 992.
Electrochemistry |
Nomenclature / Units / Symbols |
Electrolytic / Galvanic Cells / Potentials
Electrochemical conventions: Responses to a provocative opinion (2)  Castellan, Gilbert W.
The difficulty is not so much confusion over conventions as the actual wrong use of terminology.
Castellan, Gilbert W. J. Chem. Educ. 1990, 67, 991.
Electrochemistry |
Nomenclature / Units / Symbols |
Electrolytic / Galvanic Cells / Potentials
Electrochemical conventions: Responses to a provocative opinion (1)  Freeman, Robert D.
There is no convincing evidence of confusion regarding electrochemical conventions and the author's proposed solutions are unacceptable.
Freeman, Robert D. J. Chem. Educ. 1990, 67, 990.
Electrochemistry |
Nomenclature / Units / Symbols |
Electrolytic / Galvanic Cells / Potentials
Membrane material for a galvanic cell  Eggleton, Gordon L; Williamson, John J.; Johnson, Donna K.
The tubes for each electrode are prepared from a disposable polystyrene serological pipet.
Eggleton, Gordon L; Williamson, John J.; Johnson, Donna K. J. Chem. Educ. 1990, 67, 527.
Electrolytic / Galvanic Cells / Potentials |
Electrochemistry
Why the Daniell cell works!  Martins, George F.
The strength of bonds between atoms in metals, the relative ease of removing electrons from atoms, and the energy lowering of the attraction of water molecules for positive ions in solution all aid beginning student's understanding of why reactions occur.
Martins, George F. J. Chem. Educ. 1990, 67, 482.
Atomic Properties / Structure |
Metals |
Electrolytic / Galvanic Cells / Potentials
Redox reactions and the electropotential axis   Vella, Alfred J.
An introductory discussion should not get bogged down with the problems of representing cells by standard cell diagrams and notations and instead should concentrate on the chemistry of galvanic cells and the use of these cells in describing the concepts of redox chemistry.
Vella, Alfred J. J. Chem. Educ. 1990, 67, 479.
Oxidation / Reduction |
Electrolytic / Galvanic Cells / Potentials |
Electrochemistry
Construction and evaluation of an inexpensive reference electrode with internal electrolyte in agar matrix  Victoria, Leandro; Ortega, M. Gloria; Ibanez, Jose A.
In this paper the authors show how to construct a reference electrode of Ag/AgCl with an internal electrolyte in agar matrix.
Victoria, Leandro; Ortega, M. Gloria; Ibanez, Jose A. J. Chem. Educ. 1990, 67, 179.
Electrolytic / Galvanic Cells / Potentials |
Electrochemistry |
Laboratory Equipment / Apparatus
Alleviating the common confusion caused by polarity in electrochemistry  Moran, P. J.; Gileadi, E.
The issue of polarity encountered in electrochemistry and relevant to a variety of electrochemical concepts often confuses students and is an unnecessary deterrent to the study of electrochemistry.
Moran, P. J.; Gileadi, E. J. Chem. Educ. 1989, 66, 912.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Electrochemistry of the zinc-silver oxide system. Part 2. Practical measurements of energy conversion using commercial miniature cells  Smith, Michael J.; Vincent, Colin A.
Experiments in which "button cells" are discharged and charged under controlled conditions so that practical energy conversions and a number of other parameters may be studied.
Smith, Michael J.; Vincent, Colin A. J. Chem. Educ. 1989, 66, 683.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Using a projecting voltmeter to introduce voltaic cells  Solomon, Sally; Lee, Jeffrey; Schnable, Joseph; Wirtel, Anthony
Using a transparent "projecting" voltmeter and assembling a zinc versus copper cell one component at a time allows students to develop a more concrete notion of the nature of a voltaic cell and the potential it produces.
Solomon, Sally; Lee, Jeffrey; Schnable, Joseph; Wirtel, Anthony J. Chem. Educ. 1989, 66, 510.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Transformation of old two-electrode polarographs into three-electrode systems  Papadopoulos, N.; Linardis, P.
In this work a simple circuit is proposed that can transform a two-electrode polarograph into a three-electrode system.
Papadopoulos, N.; Linardis, P. J. Chem. Educ. 1989, 66, 419.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Laboratory Equipment / Apparatus
Miniware for galvanic cell experiments  Craig, Norman C.; Ackermann, Martin N.; Renfrow, William B.
The authors use a simple miniware design of a galvanic cell that is less expensive and time consuming.
Craig, Norman C.; Ackermann, Martin N.; Renfrow, William B. J. Chem. Educ. 1989, 66, 85.
Laboratory Equipment / Apparatus |
Electrolytic / Galvanic Cells / Potentials
Experimental work with tin(II) chloride in a high school   Sanchez, Manuela Martin
The author describes a final-project performed by students that integrates concepts of hydrolysis, Le Chatelier's principle, and electrolysis. Students seek answers to questions such as: "What reactions were involved; why is an aqueous solution of SnCl2 acidic; how can elemental tin be recovered from the system?"
Sanchez, Manuela Martin J. Chem. Educ. 1988, 65, 898.
Separation Science |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Equilibrium |
Oxidation / Reduction
Electrochemical cells using sodium silicate   Rapp, Bernard, FSC
A procedure of assembly and execution of a demonstration of an electrochemical cell using sodium silicate.
Rapp, Bernard, FSC J. Chem. Educ. 1988, 65, 358.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
A multi-topic problem for general chemistry   Burness, James H.
A 'marathon' problem which requires specific knowledge in several areas while requiring that the student recognize how these areas are related.
Burness, James H. J. Chem. Educ. 1988, 65, 145.
Stoichiometry |
Transport Properties |
Electrolytic / Galvanic Cells / Potentials |
Crystals / Crystallography
Electrochemistry demonstrations with an overhead projector  Ward, Charles R.; Greenbowe, Thomas J.
A template designed to fit on the surface of an overhead projector and demonstrate electrochemical phenomena.
Ward, Charles R.; Greenbowe, Thomas J. J. Chem. Educ. 1987, 64, 1021.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
More electrolysis experiments for the overhead projector  Kolb, Kenneth E.
Electrolytic cell made up of two 9-V batteries and suggestions for the electrolysis of several different materials.
Kolb, Kenneth E. J. Chem. Educ. 1987, 64, 891.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Electrodeposition of nickel on copper  Manjkow, Joseph; Levine, Dana
In the classroom, one can demonstrate electroplating by the simple, fast, inexpensive, and visually interesting reaction between nickel ions and copper metal.
Manjkow, Joseph; Levine, Dana J. Chem. Educ. 1986, 63, 809.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Oxidation / Reduction
An individualized Nernst equation experiment  Hambly, Gordon F.
Each student is assigned a target voltage for a copper / silver voltaic cell.
Hambly, Gordon F. J. Chem. Educ. 1985, 62, 875.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
An easily constructed secondary battery  Yamana, Shukichi; Murakami, Mitsuhiro
Constructing a very simple secondary battery from an aqueous solution of sodium chloride and other household materials
Yamana, Shukichi; Murakami, Mitsuhiro J. Chem. Educ. 1984, 61, 713.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Aqueous Solution Chemistry
Photoelectrochemical solar cells  McDevitt, John T.
An introduction to photoelectrochemical cells and topics pertaining to solar energy conversion.
McDevitt, John T. J. Chem. Educ. 1984, 61, 217.
Photochemistry |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Semiconductors |
Applications of Chemistry
Electrochemistry in the general chemistry curriculum  Chambers, James Q.
Students in introductory chemistry courses at large universities do not develop sufficient understanding of electrochemical phenomenon. From State-of-the-Art Symposium: Electrochemistry, ACS meeting, Kansas City, 1982.
Chambers, James Q. J. Chem. Educ. 1983, 60, 259.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Electrical energy from cells - A corridor demonstration  Gilbert, George L.
A display that demonstrates the charge and discharge of a solar cell, fuel cell, and storage cell.
Gilbert, George L. J. Chem. Educ. 1980, 57, 216.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Applications of Chemistry
Questions [and] Answers  Campbell, J. A.
330-333. Four questions and their answers; includes comments made by readers on earlier questions 130, 153, 154, 171, 172, 181.
Campbell, J. A. J. Chem. Educ. 1977, 54, 678.
Enrichment / Review Materials |
Atmospheric Chemistry |
Applications of Chemistry |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Metals |
pH
Electrochemical demonstration: Motor driven by a simple galvanic cell  Skinner, J. F.
A Zn / Zn 2+ Cu 2+ / Cu (Daniel) cell operates a small motor.
Skinner, J. F. J. Chem. Educ. 1977, 54, 619.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Aqueous Solution Chemistry
A simple lab demonstrating energy transformation  Miller, Daniel W.
Building and investigating a sulfuric acid / lead electrolytic cell.
Miller, Daniel W. J. Chem. Educ. 1977, 54, 245.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Thermodynamics
Mysterious stoichiometry  Bowman, L. H.; Shull, C. M.
The student's task in this experiment is to determine the composition of a compound of chromium produced in an electrolytic cell.
Bowman, L. H.; Shull, C. M. J. Chem. Educ. 1975, 52, 186.
Titration / Volumetric Analysis |
Quantitative Analysis |
Stoichiometry |
Aqueous Solution Chemistry |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Racing car batteries  Plumb, Robert C.; Combs, R. E.; Connelly, J. M.
Illustrating the Nernst equation and Faraday's laws using the example of the silver-zinc batteries used in racing cars.
Plumb, Robert C.; Combs, R. E.; Connelly, J. M. J. Chem. Educ. 1973, 50, 857.
Applications of Chemistry |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Questions [and] Answers  Campbell, J. A.
Six questions that can be answered with the application of basic chemical principles.
Campbell, J. A. J. Chem. Educ. 1973, 50, 847.
Enrichment / Review Materials |
Metals |
Plant Chemistry |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Applications of Chemistry
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
Definition of standard states  Lukens, David C.
A suggested sequence of definitions for the standard state.
Lukens, David C. J. Chem. Educ. 1972, 49, 654.
Thermodynamics |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Aqueous Solution Chemistry |
Solutions / Solvents
Electrochemical reactions in batteries. Emphasizing the MnO2 cathode of dry cells  Kozawa, Akiya; Powers, R. A.
The purpose of this article is to make a simplified, but current presentation of the electrochemical reactions in batteries, particularly those of the manganese dioxide cathode of dry cells.
Kozawa, Akiya; Powers, R. A. J. Chem. Educ. 1972, 49, 587.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Applications of Chemistry
The presentation of electrode potentials using an energy level diagram  Pinfold, T. A.
The tabular form in which standard electrode potentials are usually presented often leads to confusion that can be diminished by representing the electrochemical series on an energy diagram like that provided.
Pinfold, T. A. J. Chem. Educ. 1972, 49, 506.
Electrochemistry |
Oxidation / Reduction |
Electrolytic / Galvanic Cells / Potentials
Biogalvanic cells  Plumb, Robert C.; Hobey, W. D.
Explains the chemistry behind the potential development of an electrochemical cell that generates electricity using inert electrodes implanted in bodily fluids.
Plumb, Robert C.; Hobey, W. D. J. Chem. Educ. 1972, 49, 413.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Car Won't Start?  Nash, Leonard K.; Plumb, Robert C.
Examines the questions, "Does the voltage of a battery drop with temperature" and "Does the ability of a battery to deliver current decrease with temperature?"
Nash, Leonard K.; Plumb, Robert C. J. Chem. Educ. 1970, 47, 382.
Electrochemistry |
Thin Layer Chromatography |
Applications of Chemistry |
Consumer Chemistry |
Electrolytic / Galvanic Cells / Potentials
Chemical queries. Especially for introductory chemistry teachers  Young, J. A.; Malik, J. G.; House, J. E., Jr.; Campbell, J. A.
(1) When is the rule valid that the rate of reaction approximately doubles with a ten-degree temperature rise? - answer by House. (2) On the colors of transition metal complexes. (3) On an electrolysis experiment in which an acid solution is used to minimize the hydrolysis of Cu 2+. - answer by Campbell.
Young, J. A.; Malik, J. G.; House, J. E., Jr.; Campbell, J. A. J. Chem. Educ. 1969, 46, 674.
Rate Law |
Kinetics |
Transition Elements |
Coordination Compounds |
Atomic Properties / Structure |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Acids / Bases
Chemical queries. Especially for introductory chemistry teachers  Young, J. A.; Malik, J. G.; Quagliano, James V.; Danehy, James P.
(1) Why different potential for copper/zinc cells when using nitrates vs. sulfates? Why is neither cell potential as large as predicted by Nerst equation? (2) Do elements in the zinc subgroup belong to the transition series? - answer by Quagliano. (3) How can the 2,4,5-trichloro derivative of phenoxyacetic acid be prepared? - answer by Danehy.
Young, J. A.; Malik, J. G.; Quagliano, James V.; Danehy, James P. J. Chem. Educ. 1969, 46, 227.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Periodicity / Periodic Table |
Metals |
Synthesis |
Aromatic Compounds
The cell potential and the distance between electrodes  Lauren, Paul M.
This demonstration illustrates the importance of the role played by ion diffusion in determining the magnitude of the emf of a primary cell.
Lauren, Paul M. J. Chem. Educ. 1968, 45, A691.
Aqueous Solution Chemistry |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Verification of the form of the Nernst equation: An experiment for introductory chemistry  Evans, James S.
In this experiment, students record data for the concentration dependence of the ferrous-ferric half-cell potential at a platinum electrode, using a silver-silver ion reference electrode, a salt bridge, and a voltmeter.
Evans, James S. J. Chem. Educ. 1968, 45, 532.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
The Becquerel effect  Ensanian, Minas
A short note on a demonstration of the Becquerel effect.
Ensanian, Minas J. Chem. Educ. 1968, 45, 240.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Aqueous Solution Chemistry
Ionization, electricity. B. Production of electricity. C. Consumption of electricity.  Jackman, Kenneth; Ulery, Denver; Rogers, Crosby; Hornbeck, LeRoy G.; Barnard, Robert; Alyea, Hubert N.; Jackman, Kenneth V.; Burke, Christie
Demonstrations include the hydrogen electrode, H-electrode generating its own H2, consumption of electricity, Zn-Cu coupling, overvoltage, the Faraday effect, lead storage battery, and the electrolysis of NaCl.
Jackman, Kenneth; Ulery, Denver; Rogers, Crosby; Hornbeck, LeRoy G.; Barnard, Robert; Alyea, Hubert N.; Jackman, Kenneth V.; Burke, Christie J. Chem. Educ. 1966, 43, A658.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Electrode potentials  Shombert, Donald
Changes in the potential observed for two Daniell cells are due to changes in ion concentrations.
Shombert, Donald J. Chem. Educ. 1965, 42, A215.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Aqueous Solution Chemistry |
Equilibrium
Potentiometer for the general chemistry laboratory  Wood, Stanley E.; Anderson, C. B.
A circuit diagram is presented for a potentiometer used to verify the Nernst equation and investigate other electrochemical phenomenon.
Wood, Stanley E.; Anderson, C. B. J. Chem. Educ. 1965, 42, 659.
Laboratory Equipment / Apparatus |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
An experiment with galvanic cells: For the general chemistry laboratory  Dillard, Clyde R.; Kammeyer, Patty Hall
Describes a simple, low-cost galvanic cell and its use to compare various metallic electrodes.
Dillard, Clyde R.; Kammeyer, Patty Hall J. Chem. Educ. 1963, 40, 363.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Metals
Magnesium cell for demonstration  Mathur, Prem Behari; Paul, Nityanandan J.
Describes a cell system consisting of copper and magnesium plates or ribbon immersed in copper sulfate solution.
Mathur, Prem Behari; Paul, Nityanandan J. J. Chem. Educ. 1963, 40, 43.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Common sources of confusion; Electrode sign conventions  Anson, Fred C.
Examines common sources of confusion with respect to electrode signs and recommends new conventions.
Anson, Fred C. J. Chem. Educ. 1959, 36, 394.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Some demonstrations with the overhead projector  Keenan, C. W.
This paper describes the construction and use of demonstration apparatus to be used in conjunction with an overhead projector.
Keenan, C. W. J. Chem. Educ. 1958, 35, 36.
Electrochemistry |
Gases |
Electrolytic / Galvanic Cells / Potentials |
Transport Properties
Recent developments concerning the signs of electrode potentials  Licht, Truman S.; deBethune, Andre J.
It is the purpose of this paper to review recent developments concerning the signs of electrode potentials, particularly with respect to single electrode potential, half-reaction potential, and half-cell electromotive force.
Licht, Truman S.; deBethune, Andre J. J. Chem. Educ. 1957, 34, 433.
Electrochemistry |
Nomenclature / Units / Symbols |
Electrolytic / Galvanic Cells / Potentials
Movable symbols and formulas as a teaching aid  Lippincott, W. T.; Wheaton, Roger
Movable magnetic squares with symbols and formulas printed on them are used as a visual teaching aid involving a variety of fundamental chemistry concepts.
Lippincott, W. T.; Wheaton, Roger J. Chem. Educ. 1956, 33, 15.
Nomenclature / Units / Symbols |
Aqueous Solution Chemistry |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Letters  Hackney, J. C.
The author elaborates on the source of a fallacy in the calculation of an overall redox potential by combination of two half-cell potentials.
Hackney, J. C. J. Chem. Educ. 1952, 29, 472.
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials |
Aqueous Solution Chemistry |
Oxidation / Reduction
Miscellaneous experiments  Damerel, Charlotte I.
Offers three demonstrations, the first involving molecular models illustrating the generation of optical isomers in a laboratory synthesis; the second demonstrating that liquid sodium chloride conducts and electric current; and the third examining the flow of electric current in an electrochemical galvanic cell.
Damerel, Charlotte I. J. Chem. Educ. 1952, 29, 296.
Molecular Modeling |
Molecular Properties / Structure |
Chirality / Optical Activity |
Enantiomers |
Conductivity |
Electrochemistry |
Electrolytic / Galvanic Cells / Potentials
Combining half-reactions and their standard electrode potentials  Miller, Sidney I.
To increase the value of standard electrode potential tables, a new method of combination of half-cell reactions is proposed.
Miller, Sidney I. J. Chem. Educ. 1952, 29, 140.
Electrochemistry |
Aqueous Solution Chemistry |
Electrolytic / Galvanic Cells / Potentials