Chayan Das scite author profile

Role of silane-treated stöber silica as reinforcing filler for nitrile rubber (NBR) has been studied. Stöber silica is synthesized by sol-gel method, and the surface of silica is modified with the treatment of silane-coupling agent viz. g-mercaptopropyltrimethoxysilane (g-MPS) in varying proportions. Average particle size of stöber silica of spherical shape in the range of 200 to 400 nm is evident from scanning electron microscopy (SEM). Surface modification of silica particle with silane-coupling agents decreases surface energy and reduces agglomeration of silica particles in rubber matrix. Stress-strain study and dynamic mechanical analysis of silica-filled composites are compared with the unfilled ones. Analysis of cross-linking density, mechanical properties, and storage moduli indicates a strong rubber-filler interaction in the silane-treated, silica-filled NBR composites. Silane treatment is found to be effective in uniform dispersion of silica in rubber matrix and in improving the mechanical properties of rubber composite. Different functionalities of organosilane at its both end improve the compatibility of silica with rubber matrix and offer better rubber-filler interaction.

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Reinforcing efficiency and compatibilizing effect of sol–gel derived in situ silica for natural rubber/chloroprene rubber blends

Kapgate

Das

2014

RSC Adv.

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Effect of sol–gel derived in situ silica on the morphology and mechanical behavior of natural rubber and acrylonitrile butadiene rubber blends

Kapgate

Das

et al. 2012

J Sol-Gel Sci Technol

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Controlled Release of Metal Ion Cross-Linkers and Development of Self-Healable Epoxidized Natural Rubber

Mandal

Simon

Banerjee

et al. 2021

ACS Appl. Polym. Mater.

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Chemical cross-linking of rubber is a process to significantly modify the physical properties of the polymer. By this transformation, a highly viscous rubber compound is converted into an elastomer suitable for high-performance products like tires. Conventionally, sulfur or peroxide cross-linking is the preferred mode of vulcanization of the polymer practiced by different rubber industries. To fulfill the growing demand for more durable, high-performance rubber products, the development of self-healing rubber is considered one of the most promising approaches. The present study is an endeavor to mimic self-healing property in commercial epoxidized natural rubber (ENR) utilizing a mechanism that ensures the continuous supply of the healing agent to the affected area. With the advancement of metal coordination as a means of network structure, here, we report for the first time a different method for the preparation of self-healable ENR using mixed metals ions and diamine as cross-linking agents. The availability of a nitrogen coordination site of the diamine along with the reactivity of the oxirane group of epoxidized natural rubber toward metal ions enables the re-establishment of cross-linking sites in a damaged polymer network. A slow release of the metal ions from the metal amine complex to the ultra-active oxirane groups assists this reformation of the network. Additionally, some of the physical properties of the metal ion cross-linked samples are found to be comparable with those of conventional sulfur cross-linked samples.

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Effect of silane integrated sol–gel derived in situ silica on the properties of nitrile rubber

Kapgate

Das

Basu

et al. 2014

J of Applied Polymer Sci

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Nitrile rubber/silica composites are prepared by a sol-gel process using tetraethoxysilane as precursor in the presence of cmercaptopropyltrimethoxysilane as a silane coupling agent. Here, we follow a novel processing route where the silica particles are generated inside the rubber matrix before compounding with vulcanizing ingredients. The effect of in situ generated silanized silica on the properties of the rubber composite has been evaluated by studying curing characteristics, morphology, mechanical and dynamic mechanical properties. Enhanced rubber-filler interaction of these composites is revealed from stress-strain studies and dynamic mechanical analysis. Excessive use of silane shows an adverse effect on mechanical properties of the composites. Due to finer dispersed state of the in situ silica and enhanced rubber-filler interaction, the mechanical properties and thermal stability of the composites are improved compared to corresponding ex situ processed composite.

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Chayan Das

Rubber composites based on silane-treated stöber silica and nitrile rubber

Reinforcing efficiency and compatibilizing effect of sol–gel derived in situ silica for natural rubber/chloroprene rubber blends

Effect of sol–gel derived in situ silica on the morphology and mechanical behavior of natural rubber and acrylonitrile butadiene rubber blends

Controlled Release of Metal Ion Cross-Linkers and Development of Self-Healable Epoxidized Natural Rubber

Effect of silane integrated sol–gel derived in situ silica on the properties of nitrile rubber

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