Hybrid nanocrystals, fullerene-decorated graphene, were incorporated into the epoxy composites, and their electrical and thermal transport was investigated. The hybrid nanocrystals were fabricated through a solution process and the resultant hybrid nanostructure was verified by transmission electron microscopy and X-ray diffraction characterization. After incorporation of fullerene-functionalized graphene into epoxy resin, the electrical conductivity increased significantly while the thermal conductivity only increase slightly, resulting in effective decoupling thermal/electrical conductivity. Through filling fullerene/graphene nanohybrids into the epoxy resins, the electrical conductivity was increased from 10~(-14) to 2949 S/m, more than 17 orders of magnitude. On the other hand, the thermal conductivity was only increased from 0.3 to 0.66 W m~(-1)K~(-1), only two-fold increments. Further theoretical calculations and comparative experiments indicated that the synergistic effects of graphene and fullerene nanocrystals resulted in the effective decoupling of thermal/electrical transport. The electrical transport was improved through graphene sheets while the lattice thermal transport was impeded through fullerene decorated on the graphene sheets. The de-coupling of electrical and thermal conductivity of polymer composites opens numerous opportunities for new materials and systems.
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机译:杂化纳米晶体,富勒烯修饰的石墨烯,被纳入到环氧复合材料,并研究了其电和热传输。通过溶液法制备了杂化纳米晶体,并通过透射电子显微镜和X射线衍射表征验证了所得的杂化纳米结构。将富勒烯官能化的石墨烯掺入环氧树脂后,电导率显着增加,而热导率仅略有增加,从而导致热/电导率有效解耦。通过将富勒烯/石墨烯纳米杂化物填充到环氧树脂中,电导率从10〜(-14)增至2949 S / m,增幅超过17个数量级。另一方面,热导率仅从0.3 W m〜(-1)K〜(-1)增加到0.66 W m〜(-1)K〜(-1)。进一步的理论计算和比较实验表明,石墨烯和富勒烯纳米晶体的协同效应导致热/电传输的有效解耦。通过石墨烯片改善了电传输,而通过装饰在石墨烯片上的富勒烯阻碍了晶格热传输。聚合物复合材料的电导率和导热率的去耦为新材料和系统提供了许多机会。
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