Titlebook: High-Entropy Alloys; Fundamentals and App Michael C. Gao,Jien-Wei Yeh,Yong Zhang Book 2016 Springer International Publishing Switzerland 20

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書目名稱High-Entropy Alloys影響因子(影響力)




書目名稱High-Entropy Alloys影響因子(影響力)學(xué)科排名




書目名稱High-Entropy Alloys網(wǎng)絡(luò)公開度




書目名稱High-Entropy Alloys網(wǎng)絡(luò)公開度學(xué)科排名




書目名稱High-Entropy Alloys被引頻次




書目名稱High-Entropy Alloys被引頻次學(xué)科排名




書目名稱High-Entropy Alloys年度引用




書目名稱High-Entropy Alloys年度引用學(xué)科排名




書目名稱High-Entropy Alloys讀者反饋




書目名稱High-Entropy Alloys讀者反饋學(xué)科排名

Lipoprotein

Phase Formation Rules,ameters including enthalpy of mixing, entropy of mixing, melting points, atomic size difference, and valence electron concentration is used to delineate phase formation rules for HEAs, with a reference to other multicomponent alloys like bulk metallic glasses (BMGs). Specifically, rules on forming s

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Advanced Characterization Techniques,ography, high-resolution transmission electron microscopy, and neutron scattering. Applications of these techniques to characterize high-entropy alloys (HEAs) are illustrated in model alloys. Utilization of these advanced techniques can provide extremely useful structural and chemical information at

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Fabrication Routes,tered cubic (BCC), face-centered cubic (FCC), and hexagonal close-packed (HCP) lattices. The typical manufacturing routes for traditional materials can be applied to producing HEAs. Depending on how the constituent elements are mixed, the processes are divided into liquid melting, solid-state mechan

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Mechanical Properties of High-Entropy Alloys, and nanoindentation. It shows that the hardness of HEAs varies widely from 140 to 900?HV, highly depending on the alloy systems and related processing methods. The effects of annealing treatment, alloying, and structure on the hardness are discussed. The hardness at high temperatures is also summar

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Odyssey

Prediction of Structure and Phase Transformations, concepts relevant to high-entropy alloys. Specifically, we will address density functional-based calculation of .?=?0?K total energies. Extension to finite temperature will use cluster expansions for the energies to obtain the chemical substitution entropy that characterizes the high-entropy alloy

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Applications of Coherent Potential Approximation to HEAs, number of components. Two widely used CPA implementations, namely, the exact muffin-tin orbitals (EMTO) and the Korringa–Kohn–Rostoker (KKR) methods, are briefly reviewed. Applications to predict lattice stability, electronic and magnetic structure, elasticity properties, and stacking fault energie

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Applications of Special Quasi-random Structures to High-Entropy Alloys,mework and the tools available to generate SQS for high-entropy alloys (HEAs). Examples of SQS in 4- and 5-component equiatomic alloys with face-centered cubic (FCC), hexagonal close-packed (HCP), and body-centered cubic (BCC) crystal structures, which are central to HEAs, are provided with differen