A5041794054- Electromagnetic wave absorption materials
- Advancements in Battery Materials
- Recycling and Waste Management Techniques
- Energetic Materials and Combustion
- Flame retardant materials and properties
- Electromagnetic Launch and Propulsion Technology
- Metamaterials and Metasurfaces Applications
- High-Velocity Impact and Material Behavior
- Graphene and Nanomaterials Applications
- Advanced Battery Materials and Technologies
- Supercapacitor Materials and Fabrication
- Graphene research and applications
- Advanced Antenna and Metasurface Technologies
Sichuan University
2021-2022
Abstract Graphite‐derived carbon materials have been widely used in metal‐ion batteries due to their good mechanical and electrical properties, cost effectiveness, light weight, environmental friendliness. Though natural graphite has commercially lithium‐ion batteries, the small interlayer spacing hinders its application other batteries. As such, numerous works done enhance storage capability of derivatives. In this review, structural engineering on including expanded graphite, intercalation...
Here, FeAlOx catalytic deconstruction of polyethylene in a domestic microwave oven is reported. With the starting weight ratio to at 1:1, concentration and yield H2 reach up 67.85 vol% 48.1 mmol g−1plastic, respectively. CNTs@Fe3O4/Fe3C/Fe composite, which exhibits excellent absorption properties, generated simultaneously. The minimum reflection loss (RLmin) solid product reaches −54.78 dB 15 GHz with an effective bandwidth 4.5 thickness 1.57 mm.
Abstract Graphene has received intensive research interest in various areas due to its outstanding mechanical, electrical properties, high specific surface area and 2D flexible structure. Mechanical exfoliation generates defect‐free graphene, but suffers from ultra‐low yield. This drawback can be partially overcome by chemical vapor deposition method (CVD). However, conventional CVD imposes temperature. In recent years, microwave plasma‐enhanced (MPCVD) been widely investigated as a viable...
Abstract In order to investigate the damage aftereffect of energetic materials on diesel fuel tanks, this study compares effects three materials, namely CuO/Al thermite, PTFE/Al+CuO/Al composite, and Zr powder, tanks. The hole area tanks length duration deflagration-formed fireballs are characterized, process mechanism armor piercing incendiary (API) projectiles explored. According results, thermite releases energy rapidly during projectile penetration into target exhibits highest power....