This work provides a new idea for the fabrication of stretchable conductive elastomer composites with high performance. TiO 2 /CeO 2 core/shell nanostructures are synthesized at various concentrations by chemical hydrolysis method and the characterized for structural and optical properties with an intention to study the photocatalytic and photo electrochemical activities from the degradation of methylene blue and floral dye. The mechanical property of ESBR/ /SiO composite was also improved by 105.4% as compared by ESBR/CNTs. Moreover, the high electrical conductivity can be controlled at low tensile strain. The optimum electrical conductivity of the ESBR/ /SiO composites was 0.2 S/cm, which was found to be higher than that of single filler. One-dimensional (1D) were incorporated in three-dimensional (3D) spherical SiO core-shell particles, which effectively prevented the agglomeration of SiO and Again, 1D could also be used as bridges to interact with 3D SiO to develop the charge transfer more effectively in ESBR composites. ESBR composites were prepared by latex co-coagulation method, where and SiO were used to develop an 1D-3D synergistic conductive network in ESBR composites. To our knowledge, this strategy may be the rst report on heterogeneous branched coreshell SnO 2-PANI nanorod arrays. Thus, enhanced rate capability and cyclability of heterogeneous branched coreshell SnO 2PANI nanorod arrays can be anticipated. The SiO core-shell particles were prepared by coated with silver nanoparticles (AgNPs) on the surface of SiO 2 using dopamine oxidation self-polymerization and electroless plating process. 2 nanorod core by the PANI shell, ensuring the excellent structure stability. The reversible capacity of SnO(2)/WO(3) core-shell nanorods is 845.9 mA. WO(3) nanorods are uniformly coated with SnO(2) nanoparticles via a facile wet-chemical route. To measure the sensor response of the Au/SnO 2 core-shell NPs for CO gases, a sensor device was prepared as follows the synthesized Au/SnO 2 colloid was washed three times and separated by centrifugation (10,000 rpm), and then 100 L of the concentrated colloid was then dropped onto the cleaned Al 2 O 3 board (15 mm × 15 mm) with interdigitated gold electrodes (10 mm × 10 mm) and the. ![]() ![]() Non-covalent bonding modification of carbon nanotubes (CNTs) using dopamine has improved the dispersion of and interfacial interaction with the rubber matrix. The results open a way for enhancing the reversible capacity of alloy-type metal oxide anode materials with a novel mechanism by which nanostructured metallic tungsten makes extra Li(2)O (from SnO(2)) reversibly convert to Li(+). The TEM image of an individual composite nanofiber of this sample clearly reveals the coreshell structure with cellulose-derived carbon nanofiber as the core and tin oxide and molybdenum oxide nanoparticles anchored as the shell layer on the surface, and the thickness of the shell layer is about 61 nm (Fig. In the present scenario of development in technology, the applications of stretchable conductive elastomers in modern electronic equipments have aroused great interest. Hierarchical core-shell SiO 2 COFsmetallic oxide architecture: An efficient flame retardant and toxic smoke suppression for polystyrene J Colloid Interface Sci.
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