Advanced Energetic Materials: Testing and Modeling

doi:10.3390/books978-3-0365-9457-6

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https://mdpi.com/books/pdfview/book/8268

Contributor(s)

Liu, Rui (editor)

Wen, Yushi (editor)

Pang, Weiqiang (editor)

Language

English

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Abstract

To accelerate the potential applications, various works focused on the physical and chemical characteristics through theory, experiments, and simulations of advanced energetic materials (AEMs), including nano-scale energetic materials (nEMs) and micro-scale energetic materials (mEMs). This Special Issue collected comprehensive knowledge on materials synthesis, characterization, combustion, mechanical, detonation, and safety. This Special Issue, Advanced Energetic Materials: Testing and Modeling, explores innovative EMs and EMs ingredients and formulations tests and models. It collected contributions covering recent progress and models of energetic materials in chemical propulsion. Attention was focused on the design, model, properties, and state-of-the-art of this class of thermochemical propulsion devices. A total of 13 papers were selected for publication after a standard peer review process, which summarizes the most recent achievements of famous research groups. Participation of young authors with novel/innovative concepts was especially encouraged, of course, with the assistance of their supervisors.

URI

https://directory.doabooks.org/handle/20.500.12854/128801

Keywords

5-amino-1H-tetrazole; tear gas mixture; combustible agent; combustion pyrolysis characteristics; dynamics research; aluminum; oxidation process; reaction mechanism; modification method; development trend; N-oxides; cyclization reaction; synthesis; detonation performance; insensitive munition; JEOL; cook-off; ignition characteristic; Ni/Al energetic structural materials; thermal reaction; reaction kinetic model; two reaction stages; DNTF; CL-20; nanoindentation; explosive crystals; micromechanical properties; composite explosives; microfluidic; laser ignition; RDX@FOX-7; thermal analysis; micro-Raman; high-energy permanent magnets; (Sm, Zr)(Co; Cu; Fe)z alloys; as-cast state; coherent 1:5 phase; micromagnetic simulation; sandwich model; MuMax3; high-energy materials genome; artificial neural networks; burning rate; multifactor computational models; 3,4-Bis(3-nitrofurazan-4-yl) furozan (DNTF); crystallization; energetic binder GAP; mechanical sensitivity; molecular dynamics simulation; safety engineering; fragmentation impact; high-energy HTPB propellant; shock initiation; equation of state; numerical simulation; friction sensitivity; ignition; cast PBX; mesoscopic model; mitigation structure; pressure relief area; pressure relief effect; low-melting crystal; n/a