Neal R. Langley scite author profile

The theory of rubber elasticity relates the elastic modulus of unfilled amorphous rubber to the concentration of elastically effective strands. A theoretical relation between this concentration and the concentrations of potential entanglements, random tetrafunctional crosslinks, and chain ends was proposed recently. In the present work, the new relation was combined with the theory of rubber elasticity and verified experimentally. Polydimethylsiloxane samples were cured by 60Co irradiation and were extensively extracted to determine gel fraction, which was used to calculate concentrations of crosslinking and scission due to irradiation. Equilibrium modulus values determined from creep tests were in excellent agreement with those calculated using the new relation if the average spacing between potential entanglements is 116 (CH3)2SiO units. Thus, in typical commercial silicone rubbers, the contribution to the modulus from trapped entanglements is greater than the direct contribution from crosslinks. The new relation allows the calculation of crosslink concentrations from modulus measurements on other unfilled rubbers once the potential entanglement spacing of the polymer is determined.

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Dynamic Mechanical Properties of Cross-Linked Rubbers. VI. Poly(dimethylsiloxane) Networks

Langley¹,

Ferry²

1968

Macromolecules

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Improvement in Fiber Testing of High‐Modulus Single‐Filament Materials

Li¹,

Langley²

1985

Journal of the American Ceramic Society

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The standard procedure for determining the tensile strength and Young's modulus of single filament ceramic fibers (outlined in ASTM test method 0-3379-75) was modified for accurate determination of Young's modulus, especially for fibers with larger diameters. An improved plotting method to determine the system compliance factor was developed; this method allows for variations in fiber diameter and produces more accurate Young's moduli

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Physical structure of polysilicate particles in organic media

Langley

Mbah

Freeman

et al. 1991

Journal of Colloid and Interface Science

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Neal R. Langley

Elastically Effective Strand Density in Polymer Networks

Relation of elastic modulus to crosslink and entanglement concentrations in rubber networks

Dynamic Mechanical Properties of Cross-Linked Rubbers. VI. Poly(dimethylsiloxane) Networks

Improvement in Fiber Testing of High‐Modulus Single‐Filament Materials

Physical structure of polysilicate particles in organic media

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