Non-covalent chemical functionalization of micron-sized styrene-butadiene rubber with silica particles via solid-state cryogenic mixing process

IF 1.1 4区 材料科学 Q4 MATERIALS SCIENCE, COMPOSITES
Mete Bakir
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Abstract

The effective, high-value reutilization of reclaimed rubber, obtained from end-of-life tires, in the production of new high-performance tires remains an environmental and technological challenge. Cryogenically ground micron-sized rubber particles demonstrate a significant promise to realize satisfactory physical performance measures in reclaimed rubber-based tires. However, the maximum useable content of the cryogenically ground micron-sized rubber particles to be incorporated into tires is strictly limited by their ineffective interfacial chemical interactions with the host pristine rubber matrix during the post-polymerization process. Here, this work presents the non-covalent chemical functionalization of the cryogenically ground micron-sized styrene-butadiene rubber particles with reactive silica particles via a solid-state cryogenic mixing process. The highly-scalable solid-state mixing process enables the sufficiently uniform and near-homogenous distribution of the silica particles on the micron-sized rubber particles. Scanning electron microscope images highlight the micron-sized rubber particles decorated with individual silica particles. Fourier transform infrared and solid-state nuclear magnetic resonance spectra of the functionalized micron-sized rubber particles demonstrate a non-covalent conjugation mechanism between the silica and rubber particles in which the chemical fingerprint of the prime rubber backbone chains remains chemically intact. The chemically functionalized cryogenically ground micron-sized rubber particles possess reactive silica particle sites that are ultimately designed to facilitate the participation of the recycled rubber particles in post-polymerization processes with host matrix which shall allow higher loading levels than the state-of-the-art configurations.
微米级丁苯橡胶与二氧化硅颗粒的固态低温混合非共价化学功能化
从报废轮胎中获得的再生橡胶在生产新的高性能轮胎方面的有效、高价值的再利用仍然是一项环境和技术挑战。低温研磨的微米级橡胶颗粒在再生橡胶基轮胎中表现出令人满意的物理性能指标。然而,用于轮胎的低温研磨微米级橡胶颗粒的最大可用含量受到聚合后过程中它们与原始橡胶基体无效的界面化学相互作用的严格限制。在这里,这项工作提出了低温研磨微米尺寸的苯乙烯-丁二烯橡胶颗粒与反应性二氧化硅颗粒通过固态低温混合过程的非共价化学功能化。高度可扩展的固态混合工艺使二氧化硅颗粒在微米级橡胶颗粒上的分布足够均匀和接近均匀。扫描电子显微镜图像突出的微米大小的橡胶颗粒装饰单独的二氧化硅颗粒。功能化微米级橡胶颗粒的傅里叶变换红外光谱和固体核磁共振光谱表明,二氧化硅与橡胶颗粒之间存在非共价共轭机制,其中主要橡胶主链的化学指纹在化学上保持完整。化学功能化的低温研磨微米级橡胶颗粒具有活性二氧化硅颗粒位点,最终设计用于促进再生橡胶颗粒与宿主基质在聚合后过程中的参与,这将允许比最先进的配置更高的负载水平。
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来源期刊
Progress in Rubber Plastics and Recycling Technology
Progress in Rubber Plastics and Recycling Technology MATERIALS SCIENCE, COMPOSITES-POLYMER SCIENCE
CiteScore
4.40
自引率
7.70%
发文量
18
审稿时长
>12 weeks
期刊介绍: The journal aims to bridge the gap between research and development and the practical and commercial applications of polymers in a wide range of uses. Current developments and likely future trends are reviewed across key areas of the polymer industry, together with existing and potential opportunities for the innovative use of plastic and rubber products.
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