The fabrication of thin composite films incorporating metal-based fillers with a delicate structure to achieve high electromagnetic interference shielding effectiveness (EMI SE) at low metal content remains a great challenge. In this work, benefiting from the excellent electrical conductivity of Ag nanoparticles, Ag nanoparticle-coated polystyrene (PS@Ag) microspheres with a large PS core were selected as electrically conductive fillers, and the volume exclusion effect guaranteed the construction of an electrically conductive network with low silver loading. A spontaneous process to construct a segregated laminar structure with a three-dimensional electrically conductive network happened with the assistance of a gravity-driven effect. The flexible thin films with a low amount of silver exhibited outstanding EMI SE per unit thickness (SE/d). To further investigate the effect of the structure on the EMI SE efficiency, it is found that the alternate interfaces play a critical role in enhancing shielding performance by stacking multiple films compared to the bulk films obtained by casting. The EMI SE for an only 0.3 mm triple-piece stacking film with 6.3 wt % Ag loading could reach 55.3 dB compared to 37.2 dB for the triple-thickness casting film. Using the stacking process results in easy accessibility for tailored composites with the desired EMI SE, which supplies a new strategy for the design of shielding materials in the next-generation electronics.
This paper studies the structural parameters of fuel assemblies suitable for high neutron flux density environments. Due to the high neutron flux density in the core, high-flux reactors provide an experimental environment for neutron irradiation. However, high neutron flux leads to high heat flux density on the fuel assembly surface, which brings challenges to the design of fuel assembly. Therefore, it is very important to study the structural design of fuel assemblies suitable for high neutron flux density environments. Through theoretical derivation of the thermal model of the fuel assembly and sensitivity analysis of the design parameters of the fuel assembly using a single-channel program, the results show that the liquid metal cooling plate fuel element can be well adapted to the high neutron flux Density environment; at relatively low neutron flux densities, bundle fuel elements can also meet reactor design requirements.
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