Synthetic Versus Biological Networks, Volume 2, Volume 2B. T. Stokke, A. Elgsaeter The Wiley Polymer Networks Group Review Series Volume 2 Synthetic versus Biological Networks Edited by B. T. Stokke and A. Elgsaeter The Norwegian University of Science and Technology, Trondheim, Norway This, the second volume in the series, presents articles from the 14th Polymer Networks Group conference which took place in Norway in July 1998 The focus of the conference was 'Synthetic versus Biological Networks' with papers highlighting the different ideas emerging from investigations into synthetic polymer networks as opposed to, and in comparison with, polymer networks of biological origins. The papers published in this volume have been divided into six sections: Network Formation Network Characterization Polymer Networks and Precursor Architectures Biopolymer Networks and Gels Biomedical Applications of Polymer Networks Polymer Networks in Restricted Geometries |
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Page 226
... viscosity of the resin . One way to reduce the viscosity of a resin , and thus reducing the VOC , is by changing the architecture of the resin instead of changing the molar mass or chemical structure . It has been shown that the ...
... viscosity of the resin . One way to reduce the viscosity of a resin , and thus reducing the VOC , is by changing the architecture of the resin instead of changing the molar mass or chemical structure . It has been shown that the ...
Page 307
... viscosity of the suspending medium . If the viscosity is the macroscopic viscosity , nyt , T is the macroscopic stress and equation ( 25.5 ) can be rewritten by introducing a characteristic stress to which depends on the size of the ...
... viscosity of the suspending medium . If the viscosity is the macroscopic viscosity , nyt , T is the macroscopic stress and equation ( 25.5 ) can be rewritten by introducing a characteristic stress to which depends on the size of the ...
Page 315
... Viscosity ratio p = Пcont Figure 25.6 Critical capillary number C versus viscosity ratio for droplet break - up . Simple shear , turbulent and elongational flows are represented ( adapted from refs . [ 29,30 ] ) experimental ...
... Viscosity ratio p = Пcont Figure 25.6 Critical capillary number C versus viscosity ratio for droplet break - up . Simple shear , turbulent and elongational flows are represented ( adapted from refs . [ 29,30 ] ) experimental ...
Contents
80 | 6 |
CONCLUSION | 12 |
Modelling of Network Polymerization with Intramolecular | 15 |
Copyright | |
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Synthetic Versus Biological Networks, Volume 2, Volume 2 B. T. Stokke,A. Elgsaeter Snippet view - 1999 |
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1999 John Wiley amphiphilic APCNs B.T. Stokke behavior birefringence blends calculated Chem chemical concentration conetworks copolymers counter ions critical conversion cross-polymerization crosslinking curing curves cyclization decrease deformation dendrimers dependence diacetylene diacetylene-containing diffusion diol distribution double bond dynamic light scattering Edited by B.T. effect Eichinger elastic Elgsaeter end-groups equation experimental formation formed functional groups gel point gelation Group Review Series hydrogel hydrophilic hyperbranched increase inhomogeneities isocyanate kinetic light scattering linear loop structures Macromolecules macromonomer materials measurements method modulus molecular weight molecules monomer Networks Group Review NIPAAm osmotic parameters particles pendant double bond phase separation Phys PNIPA poly(ethylene glycol polyelectrolyte polyester Polymer Networks Group polymerization polyurethane prepared properties QSPR radical ratio react reactivity Review Series Vol Sakyo-ku sample shear rate shown in Figure solution solvent swollen synthesis temperature transition values viscoelastic viscosity weight fraction Wiley Polymer Networks