Reprint

Ultrasound for Material Characterization and Processing

Edited by
July 2021
188 pages
  • ISBN978-3-0365-1710-0 (Hardback)
  • ISBN978-3-0365-1709-4 (PDF)

This is a Reprint of the Special Issue Ultrasound for Material Characterization and Processing that was published in

Chemistry & Materials Science
Engineering
Physical Sciences
Summary

Ultrasonic waves are nowadays used for multiple purposes including both low-intensity/high frequency and high-intensity/low-frequency ultrasound. Low-intensity ultrasound transmits energy through the medium in order to obtain information about the medium or to convey information through the medium. It is successfully used in non-destructive inspection, ultrasonic dynamic analysis, ultrasonic rheology, ultrasonic spectroscopy of materials, process monitoring, applications in civil engineering, aerospace and geological materials and structures, and in the characterization of biological media. Nowadays, it is an essential tool for assessing metals, plastics, aerospace composites, wood, concrete, and cement. High-intensity ultrasound deliberately affects the propagation medium through the high local temperatures and pressures generated. It is used in industrial processes such as welding, cleaning, emulsification, atomization, etc.; chemical reactions and reactor induced by ultrasonic waves; synthesis of organic and inorganic materials; microstructural effects; heat generation; accelerated material characterization by ultrasonic fatigue testing; food processing; and environmental protection.This book collects eleven papers, one review, and ten research papers with the aim to present recent advances in ultrasonic wave propagation applied for the characterization or the processing of materials. Both fundamental science and applications of ultrasound in the field of material characterization and material processing have been gathered.

Format
  • Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
ultrasonic lens; axicon lens; focused ultrasound; transcranial ultrasound; non-destructive inspection; damage identification; topology optimization; ultrasonic wave propagation; ultrasonic visualization; L-shaped ultrasonic wave guide rod; ultrasonic bending vibration; 2A14 aluminum alloy; solidification structure; composition segregation; ultrasonic bending vibration; 1060 aluminum alloy; twin-roll casting; microstructure; mechanical properties; concrete; mesostructure; Lamb wave; heterogeneity; Monte Carlo method; SHM; ultrasound; time of flight; reinforcement; resin transfer molding (RTM); permeability; liquid composite molding; material characterization; composite manufacturing; liquid penetration; ultrasound transmission; capillary penetration; porous sheets; bulk metallic glass; ultrasonic assisted turning; finite element analysis; cutting force; guided waves; setting time; mortar and concrete; early age; thermoplastic composites; ultrasonic joints; resistance heating; elastography; mechanical properties; viscoelastic properties; creep; stress relaxation; n/a

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