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For the textbook, chapter, and section you specified we found
4 Videos
7 Assessment Questions
45 Journal Articles
18 Other Resources
Videos: First 3 results
Polyurethane Foam in Micro Gravity  
Polyurethane foam is formed in micro gravity (NASA Reduced Gravity Program).
Polymerization
Metallocene Catalyzed Polymerization of Ethylene  
Polymerization chemistry is demonstrated by the reaction between ethylene and a Ziegler-Natta catalyst.
Polymerization |
Catalysis |
Reactions
Formaldehyde Copolymers  
Formaldehyde Copolymers
Electrophilic Substitution |
Phenols |
Polymerization
View all 4 results
Assessment Questions: First 3 results
Special_Topics : BiopolyFromMonomer (20 Variations)
Match each of the following biomolecules to the type of biopolymer it will form.
Polymerization
Special_Topics : Copolymerization (20 Variations)
Identify the polymer produced from the polymerization of glycolic acid.

Polymerization
Special_Topics : IDMonomerFromPoly (20 Variations)
Identify the monomer used to produce the following polymer.

Polymerization
View all 7 results
Journal Articles: First 3 results.
Pedagogies:
Refractive Index Determination of Transparent Polymers: Experimental Setup for Multi-Wavelength Determination and Calculation at Specific Frequencies Using Group Contribution Theory  Jay Dlutowski, Andres M. Cardenas-Valencia, David Fries, and Larry Langebrake
A simple lab that clearly shows the dependence of light reflection on the angle of incidence for transparent polymers is described. Light transmission measurements are used to determine the reflection magnitude and the refractive index of the material.
Dlutowski, Jay; Cardenas-Valencia, Andres M.; Fries, David; Langebrake, Larry. J. Chem. Educ. 2006, 83, 1867.
Physical Properties |
Polymerization |
UV-Vis Spectroscopy
Molecular Handshake: Recognition through Weak Noncovalent Interactions  Parvathi S. Murthy
This article traces the development of our thinking about molecular recognition through noncovalent interactions, highlights their salient features, and suggests ways for comprehensive education on this important concept.
Murthy, Parvathi S. J. Chem. Educ. 2006, 83, 1010.
Applications of Chemistry |
Biosignaling |
Membranes |
Molecular Recognition |
Noncovalent Interactions |
Chromatography |
Molecular Properties / Structure |
Polymerization |
Reactions
Teaching Chemistry Laboratory Skills in Industrial Contexts  Julianne M. Braun and Carol White
A recently completed project has produced a compilation of 40 laboratory experiments presented within the contexts of five major industries. This article provides a summary of these experiments, along with a discussion of ancillary materials.
Braun, Julianne M.; White, Carol. J. Chem. Educ. 2006, 83, 353.
Applications of Chemistry |
Industrial Chemistry |
Metals |
Polymerization |
Water / Water Chemistry
View all 45 articles
Other Resources: First 3 results
Addition Polymers  Ed Vitz, John W. Moore
A section of ChemPrime, the Chemical Educations Digital Library's free General Chemistry textbook.
Polymerization
Condensation Polymers  Ed Vitz, John W. Moore
A section of ChemPrime, the Chemical Educations Digital Library's free General Chemistry textbook.
Polymerization
Copoly; A Tool for Understanding Copolymerization and Monomer Sequence Distribution of Copolymers  Massoud Miri, Juan A. Morales-Tirado
The study of the composition and monomer sequence distribution of binary copolymers is often complicated because of the many definitions of representative properties for the sequence distribution, the numerous calculations required, and occasionally the abstract treatment of the statistical processes describing the copolymer formation. Copoly resolves these issues with a user-friendly, highly visual interface to perform all calculations. Using Microsoft Excel and Word, Copoly is compatible with Windows and Mac OS. In Copoly the students enter up to five independent data parameters using the Data Input Window, and immediately see the results. To obtain diagrams for a copolymerization obeying a second-order Markovian process, the fraction of one monomer, A, and the reactivity ratios, rA, rB, rA´ and rB´ need to be entered; for a first-order Markovian process only the first three of these are required. For a Bernoullian- or zeroth-order Markovian process only A and rA are required. The results are displayed on separate sheets labeled: 1. Copolymerization Diagrams, 2. Dyads and Triads, 3. Sequence Length Distribution, 4. Simulated Copolymer Design, and 5. Summary.
Polymerization
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