Textbook-Integrated Guide to Educational Resources

TIGER

Journal Articles: 32 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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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