Phase-Separated Interpenetrating Polymer Networks |
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Page 8
... monomers and oligomers allows one to ob- tain very different materials on the basis of a relatively narrow set of initial components. What is really interpenetrating in IPNs is the penetration of the prob- lem connected with their ...
... monomers and oligomers allows one to ob- tain very different materials on the basis of a relatively narrow set of initial components. What is really interpenetrating in IPNs is the penetration of the prob- lem connected with their ...
Page 9
... monomer II and cross-linking agent and is then polymerized in situ. Thus, in sequential IPNs the synthesis of one network follows the synthesis of the other. (ii) Simultaneous IPNs, where the monomers or prepolymers and cross- linking ...
... monomer II and cross-linking agent and is then polymerized in situ. Thus, in sequential IPNs the synthesis of one network follows the synthesis of the other. (ii) Simultaneous IPNs, where the monomers or prepolymers and cross- linking ...
Page 10
... monomers or oligomers containing two or more reactive groups capable of chemical interaction , or from macromolecules containing in the main. Formation and Structure of Amorphous Polymer Networks Thermodynamics and Phase Separation in ...
... monomers or oligomers containing two or more reactive groups capable of chemical interaction , or from macromolecules containing in the main. Formation and Structure of Amorphous Polymer Networks Thermodynamics and Phase Separation in ...
Page 11
... monomer mixture ( 1 – Vc ) and current swelling degree ( 1 - VC ) , i.e. , Vc = Vo , where Vc and Vo are volume fractions of the three - dimensional polymer . By increasing the cross - linking density , the equilibrium becomes distorted ...
... monomer mixture ( 1 – Vc ) and current swelling degree ( 1 - VC ) , i.e. , Vc = Vo , where Vc and Vo are volume fractions of the three - dimensional polymer . By increasing the cross - linking density , the equilibrium becomes distorted ...
Page 19
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Contents
3 | |
4 | |
Contents | 23 |
2 | 35 |
70 | 52 |
Heterogeneous Structure and Morphology of IPNs | 65 |
5 | 67 |
6 | 73 |
8 | 137 |
5 | 147 |
of IPN Formation | 157 |
6 | 168 |
of Polyurethane and Polymerization of Butyl Methacrylate | 169 |
Kinetics of Formation of Sequential IPNs | 179 |
of SemiIPNs During Their Formation | 186 |
137 | 194 |
8 | 75 |
Characterization of IPN Structure via SmallAngle Neutron Scattering | 84 |
4 | 106 |
3 | 116 |
2 | 119 |
5 | 124 |
7 | 129 |
2 | 201 |
4 | 208 |
References | 218 |
Prof Ian Manners 55128 Mainz Germany | 219 |
Advances in Polymer Science | 223 |
Other editions - View all
Phase-Separated Interpenetrating Polymer Networks Yuri S. Lipatov,Tatiana Alekseeva Limited preview - 2007 |
Phase-Separated Interpenetrating Polymer Networks Yuri S. Lipatov,Tatiana Alekseeva No preview available - 2010 |
Phase-Separated Interpenetrating Polymer Networks Yuri S. Lipatov,Tatiana Alekseeva No preview available - 2009 |
Common terms and phrases
activation energy based on PU blends calculated chains changes characterized chemical compared compatibilization components composition concentration constituent networks conversion degree copolymer cross-linked PU cross-linking density curing decrease determined domains dynamic mechanical effect elastic modulus epoxy equation evolved phases free energy free volume gelation glass transition temperatures heterogeneous structure increase initial interaction interfacial interpenetrating interphase ionomer IPN formation IPNs based kinetics of IPN Lipatov YS mass matrix maximum microphase separation microregions miscibility mixture modulus molecular molecular mass monomer morphology network formation nonequilibrium onset of phase OUDM parameters particles PBMA phase separation PMMA polymer polymer networks polymerization PU formation PU network PU/PBMA PU/PS pure PU ratio reaction kinetics reaction rate region relaxation result scattering second network segregation degree semi-IPNs sequential IPNs simultaneous IPNs spinodal decomposition structure of IPNs styrene temperature dependence thermodynamic thermoplastic thermoplastic AIPNs tion two-phase values viscoelastic viscoelastic properties viscosity volume fraction