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Autores principales: Yakovlev, Ilya, Sztucki, Michael, Fleck, Frank, Karimi-Varzaneh, Hossein Ali, Lacayo-Pineda, Jorge, Vatterott, Christoph, Giese, Ulrich
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2407.08541
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author Yakovlev, Ilya
Sztucki, Michael
Fleck, Frank
Karimi-Varzaneh, Hossein Ali
Lacayo-Pineda, Jorge
Vatterott, Christoph
Giese, Ulrich
author_facet Yakovlev, Ilya
Sztucki, Michael
Fleck, Frank
Karimi-Varzaneh, Hossein Ali
Lacayo-Pineda, Jorge
Vatterott, Christoph
Giese, Ulrich
contents When silica-filled rubber compounds are deformed, structural modifications in the material's bulk lead to irreversible damage, the most significant of which is cavitation appearing within the interfaces of interconnected polymer and filler networks. This work introduces a new method to analyze cavitation in industrial-grade rubbers based on Ultra Small-Angle X-ray Scattering. This method employs a specially designed multi-sample stretching device for high-throughput measurements with statistical relevance. The proposed data reduction approach allows for early detection and quantification of cavitation while providing at the same time information on the hierarchical filler structures at length scales ranging from the primary particle size to large silica agglomerates over four orders of magnitude. To validate the method, the scattering of SSBR rubber compounds filled with highly dispersible silica at different ratios was measured under quasi-static strain. The strain was applied in incremental steps up to a maximum achievable elongation or breakage of the sample. From the measurements performed in multiple repetitions, it was found that the minimum strain necessary for cavity formation and the size evolution of the cavities with increasing strain are comparable between these samples. The sample with the highest polymer content showed the lowest rate of cavity formation and higher durability of silica structures. The structural stability of the compounds was determined by the evolution of the filler hierarchical structures, obtained by fitting data across the available strain range.
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publishDate 2024
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spellingShingle Cavity Formation in Silica-Filled Rubber Compounds Observed During Deformation by Ultra Small-Angle X-Ray Scattering
Yakovlev, Ilya
Sztucki, Michael
Fleck, Frank
Karimi-Varzaneh, Hossein Ali
Lacayo-Pineda, Jorge
Vatterott, Christoph
Giese, Ulrich
Applied Physics
When silica-filled rubber compounds are deformed, structural modifications in the material's bulk lead to irreversible damage, the most significant of which is cavitation appearing within the interfaces of interconnected polymer and filler networks. This work introduces a new method to analyze cavitation in industrial-grade rubbers based on Ultra Small-Angle X-ray Scattering. This method employs a specially designed multi-sample stretching device for high-throughput measurements with statistical relevance. The proposed data reduction approach allows for early detection and quantification of cavitation while providing at the same time information on the hierarchical filler structures at length scales ranging from the primary particle size to large silica agglomerates over four orders of magnitude. To validate the method, the scattering of SSBR rubber compounds filled with highly dispersible silica at different ratios was measured under quasi-static strain. The strain was applied in incremental steps up to a maximum achievable elongation or breakage of the sample. From the measurements performed in multiple repetitions, it was found that the minimum strain necessary for cavity formation and the size evolution of the cavities with increasing strain are comparable between these samples. The sample with the highest polymer content showed the lowest rate of cavity formation and higher durability of silica structures. The structural stability of the compounds was determined by the evolution of the filler hierarchical structures, obtained by fitting data across the available strain range.
title Cavity Formation in Silica-Filled Rubber Compounds Observed During Deformation by Ultra Small-Angle X-Ray Scattering
topic Applied Physics
url https://arxiv.org/abs/2407.08541