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Journal Articles: 22 results
Greener Alternative to Qualitative Analysis for Cations without H2S and Other Sulfur-Containing Compounds  Indu Tucker Sidhwani and Sushmita Chowdhury
The classic technique for the qualitative analysis of inorganic salts and mixtures relies on highly toxic hydrogen sulfide. Increasing environmental awareness has prompted the development of a green scheme for the detection of cations by spot tests that is simple and fast.
Sidhwani, Indu Tucker; Chowdhury, Sushmita. J. Chem. Educ. 2008, 85, 1099.
Green Chemistry |
Qualitative Analysis |
Separation Science
Developing and Disseminating NOP: An Online, Open-Access, Organic Chemistry Teaching Resource To Integrate Sustainability Concepts in the Laboratory  Johannes Ranke, Müfit Bahadir, Marco Eissen, and Burkhard König
Describes a project that identifies parameters for sustainable practices in organic chemistry laboratories, including the atom economy and energy efficiency of chemical transformations, questions of waste and renewable feedstocks, toxicity and ecotoxicity, and safety measures.
Ranke, Johannes; Bahadir, Müfit; Eissen, Marco; König, Burkhard. J. Chem. Educ. 2008, 85, 1000.
Green Chemistry |
Synthesis |
Toxicology
A Simplified Model To Predict the Effect of Increasing Atmospheric CO2 on Carbonate Chemistry in the Ocean  Brian J. Bozlee, Maria Janebo, and Ginger Jahn
The chemistry of dissolved inorganic carbon in seawater is reviewed and used to predict the potential effect of rising levels of carbon dioxide in the atmosphere. It is found that calcium carbonate may become unsaturated in cold surface seawater by the year 2100, resulting in the destruction of calcifying organisms such as coral.
Bozlee, Brian J.; Janebo, Maria; Jahn, Ginger. J. Chem. Educ. 2008, 85, 213.
Applications of Chemistry |
Aqueous Solution Chemistry |
Atmospheric Chemistry |
Equilibrium |
Green Chemistry |
Water / Water Chemistry
Completing Our Education. Green Chemistry in the Curriculum  Birgit Braun, Reagan Charney, Andres Clarens, Jennifer Farrugia, Christopher Kitchens, Carmen Lisowski, David Naistat, and Adam O'Neil
Identifies areas of green chemistry that are often neglected, describes the value of integrating green chemistry principles in today's curricula, and and suggests strategies educators might use to incorporate green chemistry in their classrooms.
Braun, Birgit; Charney, Reagan; Clarens, Andres; Farrugia, Jennifer; Kitchens, Christopher; Lisowski, Carmen; Naistat, David; O'Neil, Adam. J. Chem. Educ. 2006, 83, 1126.
Green Chemistry
Going Green: Lecture Assignments and Lab Experiences for the College Curriculum  Julie A. Haack, James E. Hutchison, Mary M. Kirchhoff, and Irvin J. Levy
This paper provides an overview of green chemistry, including ways to incorporate green chemistry principles in existing courses and laboratories. Green chemistry experiments previously published in this Journal are listed.
Haack, Julie A.; Hutchison, James E.; Kirchhoff, Mary M.; Levy, Irvin J. J. Chem. Educ. 2005, 82, 974.
Green Chemistry
Water in the Atmosphere  Joel M. Kauffman
None of eight college-level general chemistry texts gave a mean value for water in the atmosphere, despite its being the third most prevalent constituent at about 1.5% by mass as vapor and about 2% if clouds and ice crystals are included. The importance of water as a greenhouse gas was omitted or marginalized by five of the eight texts. An infrared spectrum of humid air was determined to demonstrate that water vapor, because of its higher concentration, was more absorptive than carbon dioxide. The cooling effect of clouds, or other influences on the Earth's albedo, were not mentioned in most of the texts. These pervasive errors should be corrected in new or future editions of textbooks.
Kauffman, Joel M. J. Chem. Educ. 2004, 81, 1229.
Atmospheric Chemistry |
Gases |
Green Chemistry |
IR Spectroscopy
News from Online: Green Chemistry  Erich S. Uffelman
An introductory, non-exhaustive set of online resources is presented to provide readers with an entry into the area of green chemistry.
Uffelman, Erich S. J. Chem. Educ. 2004, 81, 172.
Green Chemistry
Introducing Green Chemistry in Teaching and Research  Terrence J. Collins
Efforts to integrate environmental considerations into the undergraduate chemistry curriculum and description of a course entitled "Introduction to Green Chemistry".
Collins, Terrence J. J. Chem. Educ. 1995, 72, 965.
Green Chemistry
Highlights: Ventures in freshman chemistry   Farrar, James M.; Eisenberg, Richard; Kampmeier, J. A.
A rigorous freshman chemistry course that prepares students for further study in chemistry and natural sciences ties principles of chemistry to energy and environment.
Farrar, James M.; Eisenberg, Richard; Kampmeier, J. A. J. Chem. Educ. 1993, 70, 847.
Administrative Issues |
Green Chemistry |
Applications of Chemistry
Introducing the treatment of waste and wastewater in the general chemistry course: Applying physical and chemical principles to the problems of waste management  Dhawale, S. W.
Students learn simple lab techniques so that they can discuss applications such as cleanup of small-scale oil spills and the processes used to obtain drinkable pure water.
Dhawale, S. W. J. Chem. Educ. 1993, 70, 395.
Water / Water Chemistry |
Green Chemistry |
Applications of Chemistry
Teaching risk assessment in undergraduate chemistry using BCTC  Pharr, Daniel Y.
148. Bits and pieces, 49. The role of many scientists has become one of making policy decisions based on scientific data that is often incomplete and ambiguous. Having students go through the types of decisions that such scientists need to make by using the BCTC computer simulations can be a useful exercise to teach students how to research, collect, analyze, and interpret data.
Pharr, Daniel Y. J. Chem. Educ. 1993, 70, 294.
Green Chemistry
Interactive chemistry teaching units developed with the help of the local chemical industry: Applying classroom principles to the real needs of local companies to help students develop skill in teamwork, communications, and problem solving  Pontin, J. A.; Arico, E.; Pitoscio Filho, J.; Tiedemann, P. W.; Isuyama, R.; Fettis, G. C.
As part of a process of effective curriculum innovation, the authors are developing a project to produce teaching materials for chemistry undergraduate courses with an emphasis on the concerns of the local chemical industry.
Pontin, J. A.; Arico, E.; Pitoscio Filho, J.; Tiedemann, P. W.; Isuyama, R.; Fettis, G. C. J. Chem. Educ. 1993, 70, 223.
Applications of Chemistry |
Green Chemistry |
Industrial Chemistry |
Student-Centered Learning
Present and Future Nuclear Reactor Designs: Weighing the Advantages and Disadvantages of Nuclear Power with an Eye on Improving Safety and Meeting Future Needs  Miller, Warren F., Jr.
An overview of how nuclear energy is produced on macroscopic and microscopic scales with consideration given to benefits and liabilities of this energy source. The article includes a short look at nuclear power uses overseas and contains information about waste disposal, public opinion, and potential technical improvements.
Miller, Warren F., Jr. J. Chem. Educ. 1993, 70, 109.
Nuclear / Radiochemistry |
Green Chemistry |
Consumer Chemistry |
Applications of Chemistry
From Lead Solder to Kiwi Fruit: Reshaping Introductory Chemistry Labs with Investigative Team Projects  Mahaffy, Peter G.; Newman, Kenneth E.; Bestman, Hank D.
This paper reports an attempt to introduce relevant curriculum and investigations carried out by student research groups into a first year chemistry course. A description and evaluation of a four-week, open ended research project is included.
Mahaffy, Peter G.; Newman, Kenneth E.; Bestman, Hank D. J. Chem. Educ. 1993, 70, 76.
Food Science |
Consumer Chemistry |
Laboratory Management |
Vitamins |
Green Chemistry |
Minorities in Chemistry
Let environmental chemistry enrich your curriculum  Parravano, Carlo
The rationale and detailed plans for a college level course in environmental chemistry.
Parravano, Carlo J. Chem. Educ. 1988, 65, 235.
Green Chemistry |
Applications of Chemistry
A method for teaching science, technology, and societal issues in introductory high school and college chemistry classes  Streitberger, H. Eric
Most textbooks provide few, if any, systematic procedures for involving students with societal problems and issues in their lives related to chemistry. This is inconsistent with goals set in order to meet the growing need for students to be familiar with the science of (among other things) nutrition, environment, drugs, and more. This article gives a brief description of a project that acquaints students with these issues.
Streitberger, H. Eric J. Chem. Educ. 1988, 65, 60.
Consumer Chemistry |
Industrial Chemistry |
Green Chemistry |
Nuclear / Radiochemistry
The energy relationships of corn production and alcohol fermentation  Van Koevering, Thomas E.; Morgan, Michael D.; Younk, Thomas J.
The production of alcohol from corn lends itself well to illustrating the practical applications of scientific principles that deal with energy transformations and inefficiencies.
Van Koevering, Thomas E.; Morgan, Michael D.; Younk, Thomas J. J. Chem. Educ. 1987, 64, 11.
Natural Products |
Applications of Chemistry |
Plant Chemistry |
Green Chemistry |
Alcohols |
Calorimetry / Thermochemistry |
Photosynthesis
Oil shale - Heir to the petroleum kingdom   Schachter, Y.
A discussion of oil shale provides students with real-world problems that require chemical literacy.
Schachter, Y. J. Chem. Educ. 1983, 60, 750.
Applications of Chemistry |
Alkenes |
Alkanes / Cycloalkanes |
Green Chemistry
Estimating energy outputs of fuels  Baird, N. Colin
Which is the best fuel in terms of heat energy output: coal, natural gas, fuel oil, hydrogen, or alcohol? It is possible to obtain a semi quantitative estimate of the heat generated by combustion of a fuel from the balanced chemical equation alone.
Baird, N. Colin J. Chem. Educ. 1983, 60, 356.
Reactions |
Green Chemistry |
Thermodynamics |
Alcohols |
Alkanes / Cycloalkanes |
Geochemistry |
Stoichiometry |
Quantitative Analysis
Solar energy concepts in the teaching of chemistry  Cantrell, Joseph S.
A justification for why solar energy concepts should be included in the teaching of chemistry and some curricular tips for the integration of these concepts.
Cantrell, Joseph S. J. Chem. Educ. 1978, 55, 41.
Green Chemistry
Separation of waste plastics. An experiment in solvent fractionation  Seymour, Raymond B.; Stahl, G. Allan
The authors share their design for a scheme for separation of specific plastics from a mixture. This activity engages students and relates to recycling.
Seymour, Raymond B.; Stahl, G. Allan J. Chem. Educ. 1976, 53, 653.
Green Chemistry |
Separation Science |
Applications of Chemistry
The energy crisis. A new chemistry course for nonscience majors  Piraino, Marie J.
After years of having had taught traditional chemistry courses for nonscience majors, the author shifted her curriculum toward developing an understanding of political, economic, and health issues affecting contemporary students.
Piraino, Marie J. J. Chem. Educ. 1974, 51, 802.
Nonmajor Courses |
Applications of Chemistry |
Green Chemistry