Advances in Interpenetrating Polymer Networks, Volume 2 |
Contents
Synthesis | 47 |
Interpenetrating Polymer Networks as Highly Stable Metal | 73 |
PolyurethanePolydimethylsiloxane Simultaneous Interpenetrating | 101 |
The Study of Latex IPNs by CryoTEM Using | 141 |
Sulfonic Acid Resins with Interpenetrating Polymer | 157 |
Interpenetrating Polymer Networks in Acrylic Blends | 205 |
Combined Foam Plastics Based on UrethanePhenolic Oligomers | 239 |
Recent Developments in IPNs from Castor Oil | 281 |
Common terms and phrases
acid acrylate acrylic fibers AIBN AVAC blend fibers calculated castor oil cells chains Chem chemical component composition concentration copolymer CPUF cr-POE crosslink density curves decrease dielectric diisocyanate dodecane dynamic mechanical effect elastic elastic modulus elastomers electron elution entanglement epoxy resin ethanol extractant films frequency full-IPN G-SIN homopolymer increase Interpenetrating Polymer Networks ion exchange IPN and PAE IPN formation IPN PAE IPN resins K. C. Frisch kC/m² kg/m³ Klempner L. H. Sperling laminates latex loss loss tangent mechanical properties membrane metal ion methacrylic acid mixture modulus monomer morphology n₁ n₂ oligomer PAC/AS PAC/AVAC particles peaks permeability phase separation phenolic urethane foam plasticizers PMMA POE:PAA polyester polymer blends polymeric polystyrene polyurethane prepared prepolymer PU/Epoxy PU/PDMS IPNs ratio reaction S-IPN samples Santicizer semi-IPN shown in Figure SIPNs solution solvent specimen stability structure struts styrene synthesis temperature tensile strength toluene values