Polymer Dynamics and Relaxation
$55.99 ( ) USD
- Authors:
- Richard Boyd, University of Utah
- Grant Smith, University of Utah
- Date Published: March 2011
- availability: This ISBN is for an eBook version which is distributed on our behalf by a third party.
- format: Adobe eBook Reader
- isbn: 9780511888878
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Polymers exhibit a range of physical characteristics, from rubber-like elasticity to the glassy state. These particular properties are controlled at the molecular level by the mobility of the structural constituents. Remarkable changes in mobility can be witnessed with temperature, over narrow, well defined regions, termed relaxation processes. This is an important, unique phenomenon controlling polymer transition behaviour and is described here at an introductory level. The important types of relaxation processes from amorphous to crystalline polymers and polymeric miscible blends are covered, in conjunction with the broad spectrum of experimental methods used to study them. In-depth discussion of molecular level interpretation, including atomistic level computer simulations and applications to molecular mechanism elucidation, are discussed. The result is a self-contained approach to polymeric interpretation suitable for researchers in materials science, physics and chemistry interested in the relaxation processes of polymeric systems.
Read more- Phenomenological descriptions are introduced along with the principles underlying the experimental methods in order to help understanding
- Many chapters have an appendix to develop the molecular theory, and to include connection with simulations
- Results from experimental methods, and of simulations and theories, are included where appropriate
Reviews & endorsements
"Boyd and Smith (both at the U. of Utah) have written an authoritative text describing the relaxation processes of polymers and the many methods used for their study that will be essential reading for researchers and graduate students of materials science, physics, and chemistry. The initial 5 chapters are devoted to methodology, with descriptions of mechanical and dielectric relaxation, NMR spectroscopy, dynamic neutron scattering, and molecular dynamics simulations of amorphous polymers. The three stages from primary transition region, secondary (subglass) relaxations, and the transition from melt to glass of amorphous polymers are described in separate chapters, with discussion of the molecular basis of the transition from melt to glass. The volume concludes with discussion of semi-crystalline polymers and miscible polymer blends, including the models for miscible blend dynamics. Two appendices describe the Rouse model and site models for localized relaxation." Book News, Inc.
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×Product details
- Date Published: March 2011
- format: Adobe eBook Reader
- isbn: 9780511888878
- availability: This ISBN is for an eBook version which is distributed on our behalf by a third party.
Table of Contents
Preface
Part I. Methodology:
1. Mechanical relaxation
2. Dielectric relaxation
3. NMR spectroscopy
4. Dynamic neutron scattering
5. Molecular dynamics (MD) simulations of amorphous polymers
Part II. Amorphous Polymers:
6. The primary transition region
7. Secondary (subglass) relaxations
8. The transition from melt to glass and its molecular basis
Part III. Complex Systems:
9. Semi-crystalline polymers
10. Miscible polymer blends
Appendix 1. The Rouse Model
Appendix 2. Site models for localized relaxation
Index.
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