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Acta Cryst. (2014). A70, C1327
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Filler nanoparticles such as carbon black and silica play a vital role in the reinforcement effect of rubber, whereby its viscoelastic and mechanical properties are dramatically improved. The reinforcement effect is of great importance for developing rubber products such as vehicle tires. Its mechanism, however, has not been clarified despite a large number of studies. We have aimed at elucidating the mechanism by clarifying the spatio-temporal hierarchical structure of filler nanoparticles in rubber with various X-ray scattering techniques: ultra-small-angle X-ray scattering (USAXS) for elucidating the hierarchical structures of filler aggregates and their deformation under stretching, and X-ray photon correlation spectroscopy (XPCS) for observing the translational and rotational dynamics of nanoparticles in rubber. For that purpose, we have developed time-resolved two-dimensional USAXS at BL20XU [1] and XPCS at BL40XU, SPirng-8 [2, 3]. Based on the results of these novel scattering experiments, we have characterized spatio-temporal structure of filled rubber system, thereby developing tire products. In this presentation, experimental details and their results will be presented.

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Acta Cryst. (2014). A70, C1331
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Addition of nanoparticles into rubber is indispensable process for production of rubbery materials, as it improves the viscoelastic and mechanical properties of rubber (reinforcement effect). However, the understanding of reinforcement effect is far from satisfactory in spite of many studies. Further microscopic-scale investigation is required for controlling and improving the properties of rubbery materials. Aiming to construct a microscopic model of filled rubber under elongation, we have investigated nanoparticle dynamics in uniaxially stretched rubber using heterodyne X-ray photon correlation spectroscopy (heterodyne XPCS)[1] at BL03XU, SPring-8, Japan. In heterodyne XPCS, information on the fluctuating and dissipative dynamics of nanoparticles and that on their advective motion are separately extracted from the time correlation of X-ray scattering intensity. The results of heterodyne XPCS experiments showed that the direction of nanoparticles' advective motion corresponds to the macroscopic deformation of the sample in stress relaxation process. Furthermore, we found that chemical bond between nanoparticle and rubber polymer influences the dynamics of nanoparticles. In this presentation, we will show detailed analysis of the heterodyne XPCS results and discuss a microscopic description of filled rubber under elongation. This study was conducted under the approval of the SPring-8 Proposal Advisory Committee (2013A7210, 2013B7259).
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