![]() The strong enthalpic interaction between (Ni,Co) and (Al,Ti) pairs in FeCrCoAlTi 0.5Ni x ( x = 0.5–1.5) induced phase partitions into B2 (ordered phase, hard) matrix and A2 (disordered phase, soft) precipitates, resulting in a hierarchical structure of B2 grains and sub-grains of near-coherent A2 nanodomains (∼ 12.5 nm) divided by A2 interdendritic regions. Herein we report using composition design (i.e., enthalpy engineering) to create hierarchical, nanostructured HEAs as demonstrated by adding Ni into FeCrCoAlTi 0.5 HEA. However, the construction of heterogeneous nanostructured HEAs remains elusive and can involve delicate processes that are not practically scalable. Hybrid.Heterogeneous nanostructured metals are emerging strategies for achieving both high strength and ductility, which are particularly attractive for high entropy alloys (HEAs) to combine the synergistic enhancements from multielement composition, grain boundaries, and heterogeneity effects. Lends insight into the complexities of multiple atomic interactions (electronic, chemical, mechanical, magnetic) in multi-component materials Opens up the full field of multi-component and high-entropy alloys to materials and component designers and engineers. Rapid publication of short communicationsīrings together researchers working on metals, ceramics and semiconductors.īrings together researchers working on structural and functional materials. Single focus on high-entropy and medium-entropy materials. The journal publishes original, full-length, peer-reviewed papers review papers (by invitation) and short technical communications The journal is a forum for scientists and engineers who are interested in high-entropy materials, medium-entropy materials and related composites. Papers on sustainability, recyclability and the use of net-shape processing are of particular interest. Practical uses of high entropy materials of interest include: high temperature applications such as for power plants, gas turbine blades, and concentrated solar power permanent magnets and soft magnets for motors and transformers thermoelectric materials, biomaterials for prostheses, corrosion-resistant materials, cryogenic materials, and optically-absorbent materials. Papers on practical applications of high-entropy materials are particularly encouraged, as are papers on structure/property relationships and accelerated design. Papers on the thermodynamics, transformation kinetics and diffusion behavior of high-entropy materials are welcome. Papers combining properties with analytical or computational modeling (first principles density functional theory, molecular dynamics, CALPHAD, Monte Carlo simulations, phase field modeling) and advanced microstructural characterization are published. The journal covers all properties of high-entropy materials including physical (thermal expansion, heat capacity, conductivity), mechanical (quasi-static, creep, fatigue), functional (magnetic, semiconducting, optical, catalytic, antibacterial) and both corrosion and oxidation behavior. ![]() ![]() High-Entropy Alloys & Materials publishes original, peer-reviewed papers on metallic, ceramic, polymeric, organic and semiconducting high-entropy materials and medium-entropy materials that are either single-phase or multi-phase. All published articles are free to read until 2024. Call for Papers! Consider submitting your manuscript to the Special Issue, “Recent Development of High Entropy Alloys for Elevated Temperature Application.” Details are listed here.įIRST ARTICLES NOW PUBLISHED are free read below! Now OPEN FOR SUBMISSIONS! Submit your article on any aspect of High-Entropy Alloys & Materials today. ![]()
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