Advances in Interpenetrating Polymer Networks, Volume 4 |
Contents
Thermoplastic Interpenetrating Polymer Networks | 17 |
The Effect of Crosslink Density on Phase Separation | 45 |
Latex Interpenetrating Polymer Networks Based on Natural | 77 |
The Synthesis and Characterization of ThreeComponent IPNs | 109 |
Heat Resistant SemiIPNs | 141 |
Gradient Interpenetrating Polymer Networks | 191 |
IPNs Synthesized at Low Temperature and Their Application | 213 |
Means to Widen the Temperature Range of High Damping | 243 |
Fiber Reinforced Interpenetrating Polymer Networks | 287 |
Progress in in situ Sequential PolydimethylsiloxanePolymethyl | 321 |
Common terms and phrases
acrylate AIBN catalyst chain Chem chemical compatibility compatibilization component ratio concentration continuous phase crosslink density curing curves damping behavior decrease dynamic mechanical dynamic mechanical analysis effect elastomers epoxy resin ethyl acetate fiber composites fracture surface g/mol glass transition temperature gradient IPN impact strength increase Interpenetrating Polymer Networks ionomer IPN membranes J/m² K. C. Frisch Klempner L. H. Sperling latex layers linear polymer Lipatov LIPN Macromolecules materials matrix mechanical properties methacrylate methyl miscibility mixing modulus molecular weight monomer morphology natural rubber P(MA-DMA particles peak permeability coefficient phase domain phase separation PMMA polycondensation polyether polyethersulfone polyimide polymer blends polymerization polystyrene polyurethane prepared prepolymer PU/UP reaction sample scattering semi-IPNs separation factor shown in Figure shows SINS SIPNs spinodal stannous octoate Stress-strain structure styrene swelling synthesis temperature Table tensile strength thermoplastic IPNs thermosetting three-component tion toughening versus