TIGER

Journal Articles: 54 results
Construction of a Polyaniline Nanofiber Gas Sensor  Shabnam Virji, Bruce H. Weiller, Jiaxing Huang, Richard Blair, Heather Shepherd, Tanya Faltens, Philip C. Haussmann, Richard B. Kaner, and Sarah H. Tolbert
The objectives of this lab are to synthesize different diameter polyaniline nanofibers and compare them as sensor materials. Its advantages include simplicity and low cost, making it suitable for both high school and college students, particularly in departments with modest means.
Virji, Shabnam; Weiller, Bruce H.; Huang, Jiaxing; Blair, Richard; Shepherd, Heather; Faltens, Tanya; Haussmann, Philip C.; Kaner, Richard B.; Tolbert, Sarah H. J. Chem. Educ. 2008, 85, 1102.
Acids / Bases |
Aromatic Compounds |
Conductivity |
Hydrogen Bonding |
Oxidation / Reduction |
Oxidation State |
pH |
Polymerization |
Synthesis
Preparation of Conducting Polymers by Electrochemical Methods and Demonstration of a Polymer Battery  Hiromasa Goto, Hiroyuki Yoneyama, Fumihiro Togashi, Reina Ohta, Akitsu Tsujimoto, Eiji Kita, and Ken-ichi Ohshima
The electrochemical polymerization of aniline and pyrrole, and demonstrations of electrochromism and the polymer battery effect, are presented as demonstrations suitable for high school and introductory chemistry at the university level.
Goto, Hiromasa; Yoneyama, Hiroyuki; Togashi, Fumihiro; Ohta, Reina; Tsujimoto, Akitsu; Kita, Eiji; Ohshima, Ken-ichi. J. Chem. Educ. 2008, 85, 1067.
Aromatic Compounds |
Conductivity |
Electrochemistry |
Materials Science |
Oxidation / Reduction |
Polymerization
A Simple and Inexpensive Salt Bridge for Demonstrations Involving a Galvanic Cell  Charles A. Liberko
A saturated sponge is a quick, economical, and reliable way to allow ions to transfer between the two half cells in a galvanic cell.
Liberko, Charles A. J. Chem. Educ. 2007, 84, 597.
Conductivity |
Electrochemistry |
Laboratory Equipment / Apparatus
Effectiveness of a MORE Laboratory Module in Prompting Students To Revise Their Molecular-Level Ideas about Solutions  Lydia T. Tien, Melonie A. Teichert, and Dawn Rickey
This study investigates the effectiveness of a ModelObserveReflectExplain (MORE) laboratory module in prompting three different populations of general chemistry students to revise their molecular-level ideas regarding chemical compounds dissolved in water.
Tien, Lydia T.; Teichert, Melonie A.; Rickey, Dawn. J. Chem. Educ. 2007, 84, 175.
Aqueous Solution Chemistry |
Conductivity |
Ionic Bonding |
Solutions / Solvents
What Happens When Chemical Compounds Are Added to Water? An Introduction to the Model–Observe–Reflect–Explain (MORE) Thinking Frame  Adam C. Mattox, Barbara A. Reisner, and Dawn Rickey
This article describes a laboratory designed to help students understand how different compounds behave when dissolved in water, and introduces the modelobservereflectexplain (MORE) thinking frame, an instructional tool that encourages students to connect macroscopic observations with their understanding of the behavior of particles at the molecular level.
Mattox, Adam C.; Reisner, Barbara A.; Rickey, Dawn. J. Chem. Educ. 2006, 83, 622.
Aqueous Solution Chemistry |
Conductivity |
Ionic Bonding |
Solutions / Solvents |
Stoichiometry
The Reaction Quotent Is Unnecessary To Solve Equilibrium Problems. The Limitation of a Qualitative Reasoning—Editor's Note  John W. Moore
Discusses the relationship between the concentration of an aqueous solution of acetic acid, its ion concentration, and its equivalent conductance.
Moore, John W. J. Chem. Educ. 2006, 83, 384.
Aqueous Solution Chemistry |
Equilibrium |
Conductivity |
Mathematics / Symbolic Mathematics
The Reaction Quotent Is Unnecessary To Solve Equilibrium Problems. The Limitation of a Qualitative Reasoning  Rob Lederer
Discusses the relationship between the concentration of an aqueous solution of acetic acid, its ion concentration, and its equivalent conductance.
Lederer, Rob. J. Chem. Educ. 2006, 83, 384.
Aqueous Solution Chemistry |
Equilibrium |
Mathematics / Symbolic Mathematics |
Conductivity
The Reaction Quotent Is Unnecessary To Solve Equilibrium Problems. The Limitation of a Qualitative Reasoning  Paul Matsumoto
Discusses the relationship between the concentration of an aqueous solution of acetic acid, its ion concentration, and its equivalent conductance.
Matsumoto, Paul. J. Chem. Educ. 2006, 83, 383.
Equilibrium |
Mathematics / Symbolic Mathematics |
Aqueous Solution Chemistry |
Conductivity
The Reaction Quotent Is Unnecessary To Solve Equilibrium Problems. The Limitation of a Qualitative Reasoning  Michiel Vogelezang
Discusses the relationship between the concentration of an aqueous solution of acetic acid, its ion concentration, and its equivalent conductance.
Vogelezang, Michiel. J. Chem. Educ. 2006, 83, 383.
Aqueous Solution Chemistry |
Equilibrium |
Mathematics / Symbolic Mathematics |
Conductivity
The Reaction Quotent Is Unnecessary To Solve Equilibrium Problems. The Limitation of a Qualitative Reasoning  Michiel Vogelezang
Discusses the relationship between the concentration of an aqueous solution of acetic acid, its ion concentration, and its equivalent conductance.
Vogelezang, Michiel. J. Chem. Educ. 2006, 83, 383.
Aqueous Solution Chemistry |
Equilibrium |
Mathematics / Symbolic Mathematics |
Conductivity
The Preparation and Testing of a Common Emulsion and Personal Care Product: Lotion  Suzanne T. Mabrouk
First-year chemistry students can readily prepare lotion from the emulsification of deionized water, humectant, emulsifier, emollients, thickener, and preservative. Three different lotion formulations are prepared so that students can study the effects of different emulsifiers and emollients on the quality of the final product. The purpose of the ingredients is discussed.
Mabrouk, Suzanne T. J. Chem. Educ. 2004, 81, 83.
Colloids |
Conductivity |
Consumer Chemistry |
Industrial Chemistry |
Nonmajor Courses |
Applications of Chemistry
Low-Voltage Conductivity Device. Editor's Note about Using Conductivity Devices in Nonaqueous Solutions  Ed Vitz and Melissa Kistler
A conductivity demonstration device is described which operates on 12V and yet will illuminate a bulb brightly enough for use in a lecture hall, even when used with solutions of low conductivity.
Vitz, Ed; Kistler, Melissa. J. Chem. Educ. 2004, 81, 63.
Conductivity |
Laboratory Equipment / Apparatus
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
Acid-Base Indicators: A New Look at an Old Topic  Ara S. Kooser, Judith L. Jenkins, and Lawrence E. Welch
An acid-base titration in which students choose the best indicator from a set of possibilities using a conductivity probe to help them make an informed choice.
Kooser, Ara S.; Jenkins, Judith L.; Welch, Lawrence E. J. Chem. Educ. 2001, 78, 1504.
Acids / Bases |
Conductivity |
Dyes / Pigments |
Laboratory Computing / Interfacing |
Titration / Volumetric Analysis |
Quantitative Analysis
The Purification of Water by Freeze-Thaw or Zone Melting  James Oughton, Silas Xu, and Rubin Battino
Quantitative investigation of the purification of slat water solutions through the process of partial freezing.
Oughton, James; Xu, Silas; Battino, Rubin. J. Chem. Educ. 2001, 78, 1373.
Conductivity |
Phases / Phase Transitions / Diagrams |
Separation Science |
Quantitative Analysis |
Water / Water Chemistry |
Aqueous Solution Chemistry |
Solutions / Solvents
The Conductivity of Molten Materials  Monica E. Thomas, Audrey A. Cleveland, Rubin Battino, David A. Dolson, and Michael R. Hall
Demonstrating the conductivity of molten ionic compounds; includes apparatus for demonstrating conductivity and suggested list of selected test materials and their melting points.
Thomas, Monica E.; Cleveland, Audrey A.; Battino, Rubin; Dolson, David A.; Hall, Michael R. J. Chem. Educ. 2001, 78, 1052.
Conductivity |
Metals |
Ionic Bonding |
Physical Properties
Is Every Transparent Liquid Water?  Muhamad Hugerat and Sobhi Basheer
Comparisons of the properties (polarity, electric conductivity, color change due to the presence of an acid-base indicator, and electrolysis) of three transparent and colorless liquids: water, glycerol, hexane, and ethanol.
Hugerat, Muhamad; Basheer, Sobhi. J. Chem. Educ. 2001, 78, 1041.
Acids / Bases |
Electrochemistry |
Oxidation / Reduction |
Conductivity |
Electrophoresis
Solution Conductivity Apparatus  Daniel T. Haworth, Mark R. Bartelt, and Michael J. Kenney
A solution conductivity apparatus is described that can be used to measure the relative conductivity of various solutions. The apparatus can be used as either a hand-held model employing a 10-element LED display or a lecture-hall demonstration model employing a 10-incandescent-lamp array.
Haworth, Daniel T.; Bartelt, Mark R.; Kenney, Michael J. J. Chem. Educ. 1999, 76, 625.
Laboratory Equipment / Apparatus |
Conductivity |
Solutions / Solvents |
Aqueous Solution Chemistry
Chemistry for the Visually Impaired  Judy L. Ratliff
Methods used to try to provide a valuable experience for visually impaired students in a general education or an introductory chemistry class are discussed. Modifications that can be made cheaply and with little time commitment which will allow visually impaired students to participate productively in the laboratory are examined.
Ratliff, Judy L. J. Chem. Educ. 1997, 74, 710.
Laboratory Equipment / Apparatus |
Nonmajor Courses |
Minorities in Chemistry |
Conductivity |
Laboratory Equipment / Apparatus
A Low-Cost and High-Performance Conductivity Meter  Rogerio T. da Rocha, Ivano G. R. Gutz, and Claudimir L. do Lago
A two-electrode conductivimeter is described, which keep good performance in spite of its low cost.
da Rocha, Rogerio T. ; Gutz, Ivano G.R. ; do Lago, Claudimir L. J. Chem. Educ. 1997, 74, 572.
Instrumental Methods |
Conductivity |
Electrochemistry |
Laboratory Equipment / Apparatus
A Quantitative Conductance Apparatus  Danny Burns and Don Lewis
Circuitry, electrode configuration and calibration procedures are described for a conductance device. An alternative construction of the circuit is given allowing computer capture of the instrument response.
Burns, Danny; Lewis, Don. J. Chem. Educ. 1997, 74, 570.
Instrumental Methods |
Conductivity |
Liquids |
Solutions / Solvents |
Laboratory Equipment / Apparatus
Synthesis and Characterization of a Conduction Polymer: An Electrochemical Experiment for General Chemistry  Roger K. Bunting, Karsten Swarat, DaJing Yan, Duane Finello
The electrochemical synthesis of a free-standing film of polypyrrole, using commonly available equipment and materials, is described at a level suitable to application in a general chemistry laboratory. Also described are methods to quantitatively assess the doping level and to characterize the polymer film in terms of its conductivity as a function of temperature.
Bunting, Roger K.; Swarat, Karsten; Yan, DaJing; Finello, Duane. J. Chem. Educ. 1997, 74, 421.
Electrochemistry |
Conductivity
A Simple Audio Conductivity Device  Gregory Berenato and David F. Maynard
Many instruments either lack the sensitivity needed to measure small differences in conductivity or require expensive meters. To solve these problems, the authors have built a simple audio conductivity device that is very sensitive to current flow.
Berenato, Gregory; Maynard, David F. J. Chem. Educ. 1997, 74, 415.
Laboratory Equipment / Apparatus |
Conductivity
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
Glowing Veggies  Pirketta Scharlin, Audrey A. Cleveland, Rubin Battino, Monica E. Thomas, and Arnold George
In this paper we extend our work to other vegetables and the spectra generated by other elements than the sodium in pickle brines. We also did a study on the effect of concentration and voltage on glow intensity.
Scharlin, Pirketta; Cleveland, Audrey A.; Battino, Rubin; Thomas, Monica E. J. Chem. Educ. 1996, 73, 457.
Conductivity |
Food Science |
Atomic Properties / Structure
A Cheap, Semiquantitative Hand-Held Conductivity Tester  Susan K. S. Zawacky
Plans for a inexpensive, semiquantitative, hand-held conductivity tester.
Zawacky, Susan K. S. J. Chem. Educ. 1995, 72, 728.
Conductivity |
Laboratory Equipment / Apparatus
Two Safe Student Conductivity Apparatus  Katz, David A.; Willis, Courtney
Design, construction, and application of two conductivity apparatus.
Katz, David A.; Willis, Courtney J. Chem. Educ. 1994, 71, 330.
Conductivity |
Laboratory Equipment / Apparatus |
Microscale Lab
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
Classifying Substances by Electrical Character: An Alternative to Classifying by Bond Type  Nelson, P. G.
An alternative classification of substances based on their electrical properties.
Nelson, P. G. J. Chem. Educ. 1994, 71, 24.
Conductivity |
Covalent Bonding |
Ionic Bonding |
Metallic Bonding |
Semiconductors
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
A low-cost, portable, and safe apparatus for lecture hall conductivity demonstration  Mercer, Gary D.
This article describes an easily constructed apparatus for the measurement of conductivity that overcomes current restrictions and avoids bare wires.
Mercer, Gary D. J. Chem. Educ. 1991, 68, 619.
Electrochemistry |
Conductivity
Using a motor to demonstrate conductivity   Solomon, Sally; Fulep-Poszmik, Annamaria
The turning of a propeller identifies solutions of strong electrolytes.
Solomon, Sally; Fulep-Poszmik, Annamaria J. Chem. Educ. 1991, 68, 160.
Aqueous Solution Chemistry |
Solutions / Solvents |
Conductivity
An inexpensive and easily constructed device for quantitative conductivity experiments   Rettich, Timothy R.; Battino, Rubin
The low cost and easily replaced electrodes make this system practical for use in a general chemistry lab, while its accuracy and wide applicability permit its use in physical or quantitative chemistry experiments.
Rettich, Timothy R.; Battino, Rubin J. Chem. Educ. 1989, 66, 168.
Quantitative Analysis |
Conductivity |
Laboratory Equipment / Apparatus
Easily made electronic device for conductivity experiments  Gadek, Frank J.
Simple device made from a 35-mm film canister, 9-V battery and leads, resistor, and LED.
Gadek, Frank J. J. Chem. Educ. 1987, 64, 628.
Conductivity |
Laboratory Equipment / Apparatus |
Aqueous Solution Chemistry
Conductivity of solutions apparatus  Vitz, Ed
Design of simple device to demonstrate the conductivity of aqueous solutions using a pair of LED's.
Vitz, Ed J. Chem. Educ. 1987, 64, 550.
Conductivity |
Laboratory Equipment / Apparatus
A commercially available electronic device for conductivity experiments  Gadek, Frank J.
Application of a continuity and tone-generating chassis in a variety of conductivity experiments, particularly for hearing or visually impaired students.
Gadek, Frank J. J. Chem. Educ. 1987, 64, 281.
Laboratory Equipment / Apparatus |
Conductivity |
Minorities in Chemistry |
Aqueous Solution Chemistry
Quick conductivity cell  Williams, Howard P.
A simple cell for indicating the relative conductivity of electrolytes, nonelectrolytes, and weak electrolytes.
Williams, Howard P. J. Chem. Educ. 1985, 62, 799.
Electrochemistry |
Conductivity |
Laboratory Equipment / Apparatus |
Aqueous Solution Chemistry
A simple test for a conductor  Yamana, Shukichi; Yamana, Hikaru; Yamana, Hajimu
An ordinary fluorescent lamp can be used to test whether a substance is a conductor or not.
Yamana, Shukichi; Yamana, Hikaru; Yamana, Hajimu J. Chem. Educ. 1969, 46, 354.
Physical Properties |
Conductivity
Metallurgy E. Metals and Alloys  Alyea, Hubert N.; Soule, Dean; Rogers, Crosby U.
Demonstrations include the conductivity, expansion through heating, and identification of metals.
Alyea, Hubert N.; Soule, Dean; Rogers, Crosby U. J. Chem. Educ. 1967, 44, A717.
Metallurgy |
Metals |
Conductivity |
Qualitative Analysis
Ionization, Electricity D. Special electrical phenomena   Bernard, Robert; Slabaugh, W. H.
Demonstrations include cation analysis, conductivity during the titration of Ba(OH)2 + HCl vs H2C2O4, and conductivity during the titration of Ba(OH)2 + HCl vs H3PO4.
Bernard, Robert; Slabaugh, W. H. J. Chem. Educ. 1966, 43, A901.
Titration / Volumetric Analysis |
Quantitative Analysis |
Qualitative Analysis |
Electrochemistry |
Conductivity
Ionization, electricity. A. Proof that ions exist   Alyea, Hubert N.; Johnson, William.; Cocoran, Paul; Barnard, Robert; Rolf, Fred; Klug, Evangeline
Demonstrations include conductivity using a meter, conductivity of HCl in water versus in toluene, conductivity of HCl in water versus in benzene, acids plus zinc, indicators with acids and bases (H3O+ and OH-), rate of reaction and acid strengths, colors of ions, and color of cobalt ion and a cobalt complex.
Alyea, Hubert N.; Johnson, William.; Cocoran, Paul; Barnard, Robert; Rolf, Fred; Klug, Evangeline J. Chem. Educ. 1966, 43, A539.
Acids / Bases |
Conductivity |
Dyes / Pigments |
Rate Law
Electrical conductance apparatus  Steinberg, Edwin E.; Nordmann, J.
A circuit diagram for an electrical conductance apparatus that is safe, accurate, and allows for qualitative measurements.
Steinberg, Edwin E.; Nordmann, J. J. Chem. Educ. 1966, 43, 309.
Electrochemistry |
Conductivity |
Laboratory Equipment / Apparatus
Analysis of aspirin: A conductometric titration  Proctor, J. S.; Roberts, J. E.
Suggests research questions based on an earlier published article.
Proctor, J. S.; Roberts, J. E. J. Chem. Educ. 1963, 40, A306.
Undergraduate Research |
Titration / Volumetric Analysis |
Quantitative Analysis |
Electrochemistry |
Conductivity
Conduction and semiconduction  Juster, Norman J.
Reviews the conductors and semiconductors, the p-n junction, and transistors.
Juster, Norman J. J. Chem. Educ. 1963, 40, 489.
Conductivity |
Semiconductors
Electrolytic conductivity: A demonstration experiment  Thomas, William B.
Describes a simple method of measuring electrolytic conductivity based on Ohm's law.
Thomas, William B. J. Chem. Educ. 1962, 39, 531.
Electrochemistry |
Conductivity |
Solutions / Solvents |
Aqueous Solution Chemistry
Ultra Low Conductivity Water  National Bureau of Standards Summary Technical Report
Describes the production of water with a conductivity approaching the lower theoretical limit.
National Bureau of Standards Summary Technical Report J. Chem. Educ. 1961, 38, 421.
Water / Water Chemistry |
Conductivity |
Aqueous Solution Chemistry
Determination of reaction rates with an A.C. conductivity bridge: A student experiment  Chesick, J. P.; Patterson, A., Jr.
Describes a quantitative experiment in chemical kinetics suitable for advanced freshmen or physical chemistry; it involves a study of the solvolysis of tertiary butyl chloride by means of conductance measurements.
Chesick, J. P.; Patterson, A., Jr. J. Chem. Educ. 1960, 37, 242.
Conductivity |
Kinetics |
Rate Law
Textbook errors: Guest column. The solubility product constants of the metallic sulfides  Waggoner, William H.
This report reviews direct and indirect methods for investigating the solubility of substances, including conductance, potentiometric, optical, equilibrium, and thermodynamic procedures.
Waggoner, William H. J. Chem. Educ. 1958, 35, 339.
Precipitation / Solubility |
Equilibrium |
Metals |
Conductivity
The use of colloidal graphite for laboratory demonstrations  Smith, Edward A.
Examines the shape of graphite particles, the electrical properties of colloids, the coagulation of colloids, graphite and magnetic orientation, and the electrical conductivity of graphite.
Smith, Edward A. J. Chem. Educ. 1956, 33, 600.
Colloids |
Conductivity |
Magnetic Properties
Electrolytic conductivity apparatus  Schmuckler, Joseph S.; Schenck, Robert C.
Presents an apparatus that will demonstrate the conductivity of salts when fused in the solid state, in solution, and in various degrees of dilution.
Schmuckler, Joseph S.; Schenck, Robert C. J. Chem. Educ. 1956, 33, 506.
Laboratory Equipment / Apparatus |
Aqueous Solution Chemistry |
Conductivity
A device for demonstrating conductivity of solutions  Eiseman, Fred B., Jr.
An apparatus has been developed that makes it possible to demonstrate the conductivities of solutions without destroying, transferring, or contaminating them
Eiseman, Fred B., Jr. J. Chem. Educ. 1956, 33, 445.
Aqueous Solution Chemistry |
Conductivity |
Solutions / Solvents
Apparatus for the demonstration of conductivity of electrolytes  Suter, Hans A.; Kaelber, Lorraine
This device uses a continuous flow of water and a light bulb to demonstrate the conductivity of electrolytes.
Suter, Hans A.; Kaelber, Lorraine J. Chem. Educ. 1955, 32, 640.
Laboratory Equipment / Apparatus |
Aqueous Solution Chemistry |
Electrochemistry |
Conductivity
Suggestions for demonstrations  Lapp, Walter S.
The author briefly describes demonstrations involving the cathodic protection of iron from corrosion, the use of lithium in preparing hydrogen, an easily constructed conductivity kit, and a support for rubber stoppers.
Lapp, Walter S. J. Chem. Educ. 1952, 29, 611.
Oxidation / Reduction |
Conductivity |
Aqueous Solution Chemistry
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