Abstract

The physical properties of polymers depend on a range of both structural and chemical parameters, and in particular, on molecular topology. Apparently simple changes such as joining chains at a point to form stars or simply joining the two ends to form a ring can profoundly alter molecular conformation and dynamics, and hence properties. Cyclic polymers, as they do not have free ends, represent the simplest model system where reptation is completely suppressed. As a consequence, there exists a considerable literature and several reviews focused on high molecular weight cyclics where long range dynamics described by the reptation model comes into play. However, this is only one area of interest. Consideration of the conformation and dynamics of rings and chains, and of their mixtures, over molecular weights ranging from tens of repeat units up to and beyond the onset of entanglements and in both solution and melts has provided a rich literature for theory and simulation. Experimental work, particularly neutron scattering, has been limited by the difficulty of synthesizing well-characterized ring samples, and deuterated analogues. Here in the context of the broader literature we review investigations of local conformation and dynamics of linear and cyclic polymers, concentrating on poly(dimethyl siloxane) (PDMS) and covering a wide range of generally less high molar masses. Experimental data from small angle neutron scattering (SANS) and quasi-elastic neutron scattering (QENS), including Neutron Spin Echo (NSE), are compared to theory and computational predictions.

Highlights

  • The physical properties of polymer chains are very sensitive to a range of both structural and chemical parameters

  • For quasi-elastic neutron scattering (QENS), the distance scale probed is limited to a few tens of angstroms, but Neutron Spin Echo (NSE) can above 100 Å

  • A comprehensive review of synthesis and properties of cyclic polymers has been published by Kricheldorf [3] and here we briefly highlight work, relevant to our discussion

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Summary

Introduction

The physical properties of polymer chains are very sensitive to a range of both structural and chemical parameters. Recent reviews of the effect of topology on polymer chain dynamics (e.g., Richter et al [44]) have a particular focus on relatively long-range molecular motion described by the Doi Edwards reptation model. The absence of chain ends in cyclic polymers means they are a unique test of the tunneling motion driving reptation Such experimental tests require very pure fractions of high molecular weight cyclics, and, for use of the NSE technique, deuterated samples. We review the long history of theoretical and experimental studies on the effect of ring topology on conformation, local structure, and dynamics, as well as miscibility, putting in context of our own work carried out over the past 40 years using SANS and QENS neutron scattering experiments.

Neutron Scattering
Cyclic Polymers
Conformation of Cyclic Polymers in Solution
Conformation of Cyclic Polymers in the Pure Melt State
Experimental and best as obtained a blend of hydrogenated
Dynamics of Cyclic Polymers
Neutron Spin-Echo Studies
It is evident that theinternal
Intermediate scattering
Quasielastic Neutron Scattering
Blends of Polymers with
Miscibility and Conformation
Dynamics
Summary
Local and Large Scale Dynamics
Findings
Preparative

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