Physical Properties of Polymeric GelsJ. P. Cohen Addad This book emphasizes the relationship between the microscopic structure of gels and their macroscopic behaviour. Deals with organic polymeric gels, focusing on experimental methods which have only recently been introduced to study both reversible and irreversible gels. It introduce the reader with to theory and practice of physics as applied to the study of characteristics of polymeric gels and offers several clearly described basic approaches to experimental investigations into gel properties. An outstanding resource on experimental advances and modern interpretations of polymeric gel properties written by prominent experts in the field. |
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Page 1
... volume fraction occupied by the chains in the solution becomes larger and interchain interactions are more and more relevant . As long as the volume fraction occupied by the chains is much smaller than one , the solution may be ...
... volume fraction occupied by the chains in the solution becomes larger and interchain interactions are more and more relevant . As long as the volume fraction occupied by the chains is much smaller than one , the solution may be ...
Page 119
... volume explore a greater fraction of the porous voids than larger ones , and therefore will need a long time to flow through the column . The larger the hydrodynamic volume of the molecule , the shorter the time needed to flow through ...
... volume explore a greater fraction of the porous voids than larger ones , and therefore will need a long time to flow through the column . The larger the hydrodynamic volume of the molecule , the shorter the time needed to flow through ...
Page 146
... volume of the gel to the volume of the ' dry ' polymer or by the polymer volume fraction ( = 1 / 2max ) , which is then minimum . Naturally , the better the ' quality ' of the diluent , the larger the maximum swelling degree Qmax . Most ...
... volume of the gel to the volume of the ' dry ' polymer or by the polymer volume fraction ( = 1 / 2max ) , which is then minimum . Naturally , the better the ' quality ' of the diluent , the larger the maximum swelling degree Qmax . Most ...
Contents
Semidilute Polymer Solutions | 1 |
Properties of Polyelectrolyte Gels | 19 |
NMR and Statistical Structures of Gels | 39 |
Copyright | |
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Common terms and phrases
average Bastide behaviour Boué branched polymers Candau chain segments Chem chemical clusters Cohen Addad concentration fluctuations correlation length corresponding counterions crosslinking density Daoud deformation degree of swelling dependence dilute dynamics effect elastic elastic modulus excluded volume experimental exponent values Figure Flory Flory-Huggins theory fluctuations of polymer fractal dimension free energy frozen blobs function Gaussian Geissler Gennes heterogeneities idealized gels interactions larger Leibler length scales light scattering low q Macromolecules maximum swelling mean field measured mesh molecular weight molecules monomeric units monomers network chain network structure neutron scattering number of monomers observed obtained osmotic pressure PAAM parameter percolation Phys polyelectrolyte polymer chains polymer concentration polymer solutions polymeric polymeric gels polystyrene properties quenched fluctuations random relaxation sample scattering experiments scattering intensity semi-dilute solution shear modulus skeletal bonds solvent static stretching structure factor swelling degree swollen theory uniaxial vector volume fraction wave vector