Modulus recovery kinetics and other insights into the payne effect for filled elastomers

Chazeau, Laurent; Brown, J. D.; Yanyo, L. C.; Sternstein, S. S.

doi:10.1002/pc.10178

Cited by 179 publications

(156 citation statements)

References 16 publications

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“…Additionally, a static strain has no effect on the observed Payne effect. 3 Why would a glassy layer disappear when subjected to a static stress but not a dynamic stress? In summary, the glassy layer as a root cause of the reinforcement mechanism raises more questions than it answers.…”

Section: Resultsmentioning

confidence: 99%

“…It has also been shown that the Payne effect is related to the dynamic, and not static, component of the strain history and that the Payne effect would vanish at very low strain rates. 3 If a glassy layer is responsible for the high reinforcement then why does reinforcement vanish if observed at a slow strain rate? Additionally, a static strain has no effect on the observed Payne effect.…”

Section: Resultsmentioning

confidence: 99%

“…These models can be categorized based on the root origin of the phenomena, that is, some of them are based on the spatial distribution of the fillers, such as agglomeration, deagglomeration, filler percolation threshold, or the alteration of chain dynamics near the filler surface, with both short-or long-range effects and with finite bond lifetime or permanently adhered bonds that form glassy layers near the filler particles. [1][2][3][4] The presence of a glassy layer at the filler surface as the underlying mechanism of reinforcement has been proposed by several authors. [5][6][7][8] The model states that a glassy layer or layers with a gradient of glass transition temperature persists near the walls of the filler even if the temperature is above the glass transition Correspondence to: S. Amanuel (E-mail: amanuels@union.…”

Section: Introductionmentioning

confidence: 99%

“…In this regard, there are several observations that have been made in filled elastomers well above the glass transition temperature that suggest alternate explanations to the formation of a glassy layer. 3,4 These explanations are based on the labile bonding of the polymer to the filler surfaces and the resultant effects this bonding has on the reduction of conformational entropy of the matrix chains. 4 Thus, entropic hardening is the result of enthalpic bonding of the polymer segments to the filler surfaces, but this bonding need not produce a glassy layer to be effective at producing high reinforcement through far-field interactions transmitted by chain entanglements.…”

Section: Introductionmentioning

confidence: 99%

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Enthalpic relaxation of silica–polyvinyl acetate nanocomposites

Amanuel

Gaudette

Sternstein

2008

J Polym Sci B Polym Phys

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Although the effects of filler nanoparticles size and surface treatment on the glass transition temperature of the matrix phase have received well-deserved attention, nanofiller effects on other physical parameters associated with the glass transition have received less interest. To better understand how the incorporation of nanofillers affects the enthalpic relaxations associated with the glass transition, differential scanning calorimeter measurements were carried out on silica-polyvinyl acetate nanocomposites with respect to filler content, annealing temperature, and annealing period. As expected, longer annealing periods below the glass transition temperature resulted in an increase of the subsequent enthalpic relaxations. However, the presence of filler substantially reduces the enthalpic relaxation relative to that of the neat polymer at longer annealing periods only. The underlying enthalpic relaxations and the effects suppressed by the fillers are specific to the annealing temperature. These results suggest a significant alteration in the physical state of the matrix because of the presence of the filler particles. However, this does not imply the existence of a glassy layer or layers with a glass transition gradient near the filler surface.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Enthalpic relaxation of silica–polyvinyl acetate nanocomposites

Amanuel

Gaudette

Sternstein

2008

J Polym Sci B Polym Phys

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“…Viscoelastic behavior is extremely sensitive to the structure of the filler network in particlereinforced polymers, and the strain-dependence of dynamic mechanical response after complex deformation histories can reveal details of the heterogeneity and kinetics of network break-up and recovery. [48][49][50][56][57][58][59][60] When the particles are electrically conductive (e.g., carbon black), electrical resistance testing is another useful method to study the structure of the percolated filler network. [61][62][63][64] With the exception of transmission electron microtomography, 65,66 it is difficult to observe differences in the three-dimensional nature of jammed particle networks using microscopy.…”

Section: Flocculation Reinforcement and Glass Transition Effects 511mentioning

confidence: 99%

Flocculation, Reinforcement, and Glass Transition Effects in Silica-Filled Styrene-Butadiene Rubber

Robertson

Lin

Bogoslovov

et al. 2011

Rubber Chemistry and Technology

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The introduction of silanes to improve processability and properties of silica-reinforced rubber compounds is critical to the successful commercial use of silica as a filler in tires and other applications. The use of silanes to promote polymer-filler interactions is expected to limit the development of a percolated filler network and may also affect the mobility of polymer chains near the particles. Styrene-butadiene rubber (SBR) was reinforced with silica particles at a filler volume fraction of 0.19, and various levels of filler-filler shielding agent (n-octyltriethoxysilane) and polymerfiller coupling agent (3-mercaptopropyltrimethoxysilane) were incorporated. Both types of silane inhibited the filler flocculation process during annealing the uncured rubber materials, thus reducing the magnitude of the Payne effect. In contrast to the significant reinforcement effects noted in the strain-dependent shear modulus, the bulk modulus from hydrostatic compression was largely unaltered by the silanes. Addition of polymer-filler linkages using the coupling agent yielded bound rubber values up to 71%; however, this bound rubber exhibited glass transition behavior which was similar to the bulk SBR response, as determined by calorimetry and viscoelastic testing. Modifying the polymer-filler interface had a strong effect on the nature of the filler network, but it had very little influence on the segmental dynamics of polymer chains proximate to filler particles.

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Mechanical Properties of Rubber Nanocomposites: How, Why … and Then?

Chazeau¹,

Gauthier²,

Chenal³

2010

Rubber Nanocomposites

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Through the review of literature, this chapter will first recall the typical mechanical behaviour of rubber filled with nanofillers, from the viscoelastic linear behaviour to the large deformation one, including the ultimate properties. Then we will highlight the main filler parameters and how they seem to control these properties. In particular, we will focus on the role of filler-filler and filler matrix interactions, which are necessarily important when dealing with fillers with such high specific surface (up to several hundreds of meter square per gram).We will also see the influence of these fillers on the matrix properties, since, for instance, the filler presence can modify the matrix crosslinking kinetic or induce crystallization. Then, this description will be completed by the introduction of different modelling approaches developed to account for and eventually predict the role of nanofillers in the mechanical behaviour of these rubber nanocomposites.

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Modulus recovery kinetics and other insights into the payne effect for filled elastomers

Cited by 179 publications

References 16 publications

Enthalpic relaxation of silica–polyvinyl acetate nanocomposites

Enthalpic relaxation of silica–polyvinyl acetate nanocomposites

Flocculation, Reinforcement, and Glass Transition Effects in Silica-Filled Styrene-Butadiene Rubber

Mechanical Properties of Rubber Nanocomposites: How, Why … and Then?

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