## Molecular Basis of Polymer Networks: Proceedings of the 5th IFF-ILL Workshop, Jülich, Fed. Rep. of Germany, October 5–7, 1988The workshop on the "Molecular Basis of Polymer Networks", held October 5- 7, 1988 in 1iilich, FRG, continued a series of workshops jointly organized by the Institute Laue Langevin (ILL) in Grenoble, and the Institute of Solid State Physics of the KFA, 1iilich. The aim of this workshop was to provide a platform for discussions between theoreticians and experimentalists interested in the physics of polymer networks, in the hope that the two types of discussion would be synergistic. As revealed by the title of this workshop, the main focus of the lectures was on molecular aspects of the problem. The individual parts of these proceedings cover various approaches. Following quite general comments from a physicist examining the situation from "outside", various new theoretical concepts are developed. During the last decade the advent of Small Angle Neutron Scattering (SANS) has allowed the molecular structure of polymer networks to be studied and thus the reliability of the theories to be tested directly at the molecular level. Recent advances in this field are presented. The use of new techniques such as 2H NMR or QELS and the refinements of more classical, mechanical experimental measure ments have provided new information about the relation between the macroscopic behavior and the microscopic structure of polymer networks. Some recent results in this area are discussed for both chemically cross-linked networks and gels built by specific interchain interactions. |

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Page 7

Figures ( a ) and ( b ) represent two states of the same square network . Folding

can also be disordered . 10 . Entanglements . Stress Points and Cooperative

Effects We know very little about the topological

network ...

Figures ( a ) and ( b ) represent two states of the same square network . Folding

can also be disordered . 10 . Entanglements . Stress Points and Cooperative

Effects We know very little about the topological

**constraints**which exist in anetwork ...

Page 102

Deviations of real network properties from those of the phantom model are

reflected in the

< ( AR ; ) ? > given by ( 1 ) has to be modified in a manner depending on the

degree ...

Deviations of real network properties from those of the phantom model are

reflected in the

**constraints**operating on fluctuations of points along chains . Thus< ( AR ; ) ? > given by ( 1 ) has to be modified in a manner depending on the

degree ...

Page 189

The set of equations of motion for the chain is solved numerically , taking into

account the

The set of equations of motion for the chain is solved numerically , taking into

account the

**constraints**which guarantee the ... As a consequence , the forces of**constraint**acting on the fixed end points of the chain fluctuate irregularly in time .### What people are saying - Write a review

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### Contents

Remarks | 2 |

The BaumgärtnerMuthukumar Effect in Networks | 11 |

By S F Edwards With 1 Figure | 17 |

Copyright | |

18 other sections not shown

### Other editions - View all

Molecular Basis of Polymer Networks: Proceedings of the 5th IFF-ILL Workshop ... Artur Baumgärtner,Claude E. Picot No preview available - 2011 |

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appear approximation arms assumed average behaviour bonds calculated Chem chemical compared components concentration conformation connected considered constant constraints containing contribution correlations corresponding crosslinking curves deformation density dependence described deuterated dimension direction discussed distance distribution dynamics Editors Edwards effect elastic equation equilibrium expected experimental experiments exponent expression factor Figure Flory fluctuations force fractal fraction free energy function given gives increases interaction labelled larger leads length linear Macromolecules mean measurements mechanical melt method modulus molecular weight molecules motion neutron Note observed obtained orientation parameter paths PDMS Phys Physics Picot Polymer Networks predictions present probability properties range ratio reduced reference relaxation respect rods rubber sample scaling scattering segment shown shows simple solution solvent Springer star statistical stress structure studied surface swelling swollen temperature theory transition values volume