Mechanical Properties of Advanced Metallic Materials

doi:10.3390/books978-3-0365-6957-4

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https://mdpi.com/books/pdfview/book/6964

Contributor(s)

Zhang, Yang (editor)

Chen, Yuqiang (editor)

Language

English

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Abstract

We thank all contributors of this Special Issue and the editorial staff of Crystals for helping this Special Issue achieve success; we are especially gratefully to the expert reviewers who agreed to review the papers submitted to this Special Issue for their diligence and timely effort. Under joint efforts, finally, this Special Issue published 15 papers, including 1 review paper and 14 original research papers. These published papers are mainly related to the mechanical properties of superelastic alloys, titanium alloys, shape memory alloys, various kinds of steels, medium-entropy alloys, high-temperature alloys, etc. Under the success of this Special Issue, the published papers will promote the development and progress of advanced metallic materials. We sincerely hope these papers can cause the readers to be informative and inspire them to obtain new ideas.

URI

https://directory.doabooks.org/handle/20.500.12854/98911

Keywords

low cycle fatigue; microstructure; titanium alloys; thermal-mechanical alleviation; current; plasma arc cladding technology; 2205 duplex stainless steel; potentiodynamic polarization curve; passive film composition; aluminum micron powder; microwave radiation; energetic material; aluminized high-energy material; high-speed imaging; laser monitor; Fe-based alloy; superelasticity; martensitic transformation; precipitate; medium-entropy alloy; twin boundary; mechanical properties; molecular dynamics; Ti alloy; microstructure evolution; hot tensile deformation; fracture mechanism; 5083/6005A welding joint; corrosion mechanism; corrosion model; fatigue life prediction model; Cu–Al–Ag alloy; martensite; accumulative roll bonding (ARB); shape memory alloy (SMA); hybrid composites; characterization; zirconia; graphite; SEM; selective laser melting; Inconel 718 alloy; laser energy density; microhardness; laser-based powder bed fusion; titanium alloy; Taguchi; process optimization; density; A1. dendrite; A1. particle pushing; A1. diffusion; A2. growth from melt; B1. alloys; Ti alloys; β-phase; laser cladding; wear characterization; biomedical applications; physical vapor deposition; pre-oxidation; coating adhesion; titanium; ferritic stainless steel; high-manganese steel; structural steel; phase interface; reactive wetting; contact angle; refractory material