2018
DOI: 10.1002/pat.4284
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Nanocavitation in silica filled styrene‐butadiene rubber regulated by varying silica‐rubber interfacial bonding

Abstract: The influence of filler‐matrix interfacial bonding on the nanocavitation of rubber materials has not been explored clearly. We herein report the nanocavitation modes and geometrical features impacted by varying the silica‐styrene‐butadiene rubber interfacial bonding. The interfacial bonding is tuned by grafting different amount of multi‐functional silane coupling agents on to the silica nanoparticles. By using synchrotron radiation small angle X‐ray scattering measurements, 2 major classes of cavitation were d… Show more

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Cited by 15 publications
(7 citation statements)
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“…Figures 3 shows that in the 3 materials, they contain soft layers of polymer. For this reason, instead of relaxing concentration by cavitation at their poles, one observes, at sufficiently large deformation, that these CBaggl do it by their internal fracture [26] (Figure 9). Such agglomerate fracture mechanisms were previously reported in the literature for materials containing silica agglomerates that has undergone fatigue [53] or quasi-static tests [8].…”
Section: Discussionmentioning
confidence: 99%
See 1 more Smart Citation
“…Figures 3 shows that in the 3 materials, they contain soft layers of polymer. For this reason, instead of relaxing concentration by cavitation at their poles, one observes, at sufficiently large deformation, that these CBaggl do it by their internal fracture [26] (Figure 9). Such agglomerate fracture mechanisms were previously reported in the literature for materials containing silica agglomerates that has undergone fatigue [53] or quasi-static tests [8].…”
Section: Discussionmentioning
confidence: 99%
“…Although techniques like SEM [14,22,23], TEM [24] and AFM [25] provide a better resolution, use of these techniques for in-situ characterization is limited due to small observable area, small size of the sample, or to the material degradation during the observation. SAXS is a non-destructive characterization technique that provides spatially averaged information at sub-micron scale such as the average particle size, shape, distribution of defects or cavities [26]. It is however difficult to visualize or quantify the local dissipative mechanisms occurring in the crack tip vicinity using this technique.…”
Section: Introductionmentioning
confidence: 99%
“…The Q/Q 0 value increases with increasing volume fraction of voids and is independent of the shape of voids. 19,21,22 Q 0 indicates the scattering invariant of rubber without cavitation and was determined before each measurement on the undeformed sample. The scattering invariant Q is calculated by = Q I q q q dq dq ( , ) .…”
Section: Cavitation Analysis With Saxsmentioning
confidence: 99%
“…When cavities are induced in the rubber matrix due to the large difference between rubber density and the density of air, an obvious change of the scattering invariant Q could be obtained, which leads to Q / Q 0 > 1. The Q / Q 0 value increases with increasing volume fraction of voids and is independent of the shape of voids. ,, Q 0 indicates the scattering invariant of rubber without cavitation and was determined before each measurement on the undeformed sample. The scattering invariant Q is calculated by Q = prefix∫ 0.04 1.0 0.04 1.0 I ( q 12 , q 3 ) q 3 d q 12 d q 3 . …”
Section: Materials and Experimental Techniquesmentioning
confidence: 99%
“…It is important to reinforce the polymer nanocomposites (PNCs) for developing highly functional materials, such as fuel-efficient tires or oil-sealing rubber parts. [1,2] Generally, addition of a large amount of nanoparticles (NPs) into the matrix can reinforce the PNCs which however increases the difficulty in uncovering the physical mechanisms. Many parameters influence the reinforcement of PNCs such as the shape, size, content and dispersion of NPs, the polymer-NP interaction and so on.…”
Section: Introductionmentioning
confidence: 99%