Materials under High Pressure

doi:10.3390/books978-3-7258-0393-4

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Materials under High Pressure

Edited by

March 2024

236 pages

ISBN978-3-7258-0394-1 (Hardback)
ISBN978-3-7258-0393-4 (PDF)

https://doi.org/10.3390/books978-3-7258-0393-4

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This book is a reprint of the Special Issue Materials under High Pressure that was published in

Chemistry & Materials Science

Engineering

Physical Sciences

Summary

The high-pressure-related problems of materials constitute a field at the confluence of several scientific disciplines. High pressure can be generated by die compression, high-velocity impact, or explosions. An understanding of materials under extreme high pressure, including flow, plastic deformation, phase transformation, fracture, temperature rise, and chemical reactions, is needed. This Special Issue on “Materials under High Pressure” collected recent research findings on the high-pressure-related problems of various materials. A collection of fourteen peer-reviewed research articles was included in this Special Issue. The main topics covered include processing technology, characterization, testing, theoretic modeling, and simulation.

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Keywords

space harpoon; impact; friction; embedding length; launch initial velocity; dynamic analysis; modal analysis; harmonic response analysis; electronic component; fault mechanism; reactive materials; Al-PTFE-W composites; tension failure; mechanical properties; Johnson–Cook modeling; reactive material; impact initiated chemical reaction; theoretical model; PTFE/Al/oxide; shock-induced; energy release characteristic; controlling effect; shock wave; THV-based reactive materials; mechanical performances; thermal analysis; reaction threshold; energy release behavior; reactive materials (RMs); mechanical properties; constitutive model; quasi-sealed chamber test; shock-induced reaction; jet; dynamic conditions; virtual origin; penetration mechanism; shaped charge projectile; velocity attenuation law; underwater explosion; trans-media; shaped charge; trapezoid cross-section; formation; X-ray; three-stage detonation driving model; double-layer prefabricated fragments; fragment initial parameters; explosion detonation; explosive dispersal; dry powder; mass ratio; particle jet; contact blast; coatings; fragment deformation behavior; dynamic response; protection performance; pure Ti; hetero-structure; deformation mechanism; twinning; high strain rate; n/a