Polymer Interface and AdhesionPoly mer Interface and Adhesion provides the critical basis for further advancement in thisfield. Combining the principles of interfacial science, rheology, stress analysis, and fracturemechanics, the book teaches a new approach to the analysis of long standing problemssuch as: how is the interface formed; what are its physical and mechanical properties;and how does the interface modify the stress field and fracture strength of the material.The book offers many outstanding features, including extensive listings of pertinent references,exhaustive tabulations of the interfacial properties of polymers, critical reviews ofthe many conflicting theories, and complete discussions of coupling agents, adhesion promotion,and surface modifications. Emphasis is placed on physical concepts and mechanisms,using clear, understandable mathematics.Polymer Interface and Adhesion promotes a more thorough understanding of the physical,mechanical, and adhesive properties of multiphase, polymer systems. Polymer scientistsand engineers, surface chemists, materials scientists, rheologists, as well as chemical andmechanical engineers interested in the research, development or industrial applications ofpolymers, plastics, fibers, coatings, adhesives, and composites need this important newsource book. |
From inside the book
Results 1-5 of 49
Page 30
... interaction between these two dipoles averaged over all instantaneous electronic configurations is the dispersion force. Note that the interaction between instantaneous dipoles of two molecules averaged over all electronic ...
... interaction between these two dipoles averaged over all instantaneous electronic configurations is the dispersion force. Note that the interaction between instantaneous dipoles of two molecules averaged over all electronic ...
Page 32
... the London theory. Experimental confirmations of the London theory have been reported [25—29] and reviewed [4,6]. 2.1.2. Dipole-Dipole Energy (Dipole Energy) Debye [30,31] gave the interaction 32 2 / Molecular Interpretations.
... the London theory. Experimental confirmations of the London theory have been reported [25—29] and reviewed [4,6]. 2.1.2. Dipole-Dipole Energy (Dipole Energy) Debye [30,31] gave the interaction 32 2 / Molecular Interpretations.
Page 33
... interaction energy between two dipoles of fixed orientation as yly2 P U = “ [2 cos ei cos e2 ~ sin 91 sin 92 COS ^ 1 ~ r 3— (2.16) where UP is the energy of interaction, y the dipole moment, r the center-to-center distance between the ...
... interaction energy between two dipoles of fixed orientation as yly2 P U = “ [2 cos ei cos e2 ~ sin 91 sin 92 COS ^ 1 ~ r 3— (2.16) where UP is the energy of interaction, y the dipole moment, r the center-to-center distance between the ...
Page 35
... interaction, arising from headto-tail interaction of dipoles. It is not a primary chemical bond. The intermolecular energy for a hydrogen bond may formally be given as h U + H H ). (. hi. V. r ( 2.21) Table 2.3 . Segmental Polarizability ...
... interaction, arising from headto-tail interaction of dipoles. It is not a primary chemical bond. The intermolecular energy for a hydrogen bond may formally be given as h U + H H ). (. hi. V. r ( 2.21) Table 2.3 . Segmental Polarizability ...
Page 40
... interaction, A-^P the attraction constant for dipole interaction, A^1 the attraction constant for induction interaction, and A^2h the attraction constant for hydrogen bonding. These are given by A. V2. 2. 12 (2.31) 4 ala2 I 1 + I 2 A d P ...
... interaction, A-^P the attraction constant for dipole interaction, A^1 the attraction constant for induction interaction, and A^2h the attraction constant for hydrogen bonding. These are given by A. V2. 2. 12 (2.31) 4 ala2 I 1 + I 2 A d P ...
Contents
1 | |
29 | |
3 INTERFACIAL AND SURFACE TENSIONS OF POLYMER MELTS AND LIQUIDS | 67 |
4 CONTACT ANGLES OF LIQUIDS ON SOLID POLYMERS | 133 |
5 SURFACE TENSION AND POLARITY OF SOLID POLYMERS | 169 |
6 WETTING OF HIGHENERGY SURFACES | 215 |
7 DYNAMIC CONTACT ANGLES AND WETTING KINETICS | 235 |
8 EXPERIMENTAL METHODS FOR CONTACT ANGLES AND INTERFACIAL TENSIONS | 257 |
11 FORMATION OF ADHESIVE BOND | 359 |
12 WEAK BOUNDARY LAYERS | 449 |
13 EFFECT OF INTERNAL STRESS ON BOND STRENGTH | 465 |
14 FRACTURE OF ADHESIVE BOND | 475 |
15 CREEP FATIGUE AND ENVIRONMENTAL EFFECTS | 571 |
Calculation of Surface Tension and Its Nonpolar and Polar Components from Contact Angles by the HarmonicMean and the GeometricMean Methods | 613 |
Unit Conversion Tables | 619 |
Index | 621 |
MECHANISMS OF WETTABILITY AND BONDABILITY IMPROVEMENTS | 279 |
BASIC CONCEPT AND LOCUS OF FAILURE | 337 |
Other editions - View all
Common terms and phrases
acid adherend adhesive adhesive bond aluminum analysis Appl applied attraction bond bond strength bondability boundary layer bulk calculated Chem chemical cohesive Colloid Interface Sci constant contact angle crack critical cross-linked curve decrease density depends diffusion discussed drop dyne/cm Effect equation equilibrium ethylene experimental failure Figure force formed fracture energy function given gives glass groups hand increases interaction interfacial interfacial tension joint layer liquid loading lower materials maximum measured mechanical melt metal methacrylate method mode molecular molecules obtained occurs oxide peel phase Phys plasma plastic plate plot polar Poly Poly vinyl polyethylene Polym polystyrene predicted Press pressure region relation rubber separation shear shown shows silane solid solution specimen spreading strength stress surface tension Table temperature tensile term theory thickness tion treated treatment unit values various versus volume weight wettability wetting York zero