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High Entropy Alloys(2021)
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Research Progress on Deformation Mechanisms Under Dynamic Loading of High-Entropy Alloys
WANG Ruixin, TANG Yu, LI Shun, BAI Shuxin
Materials Reports
2021,35(17 ):17001 -17009. DOI:10.11896/cldb.21040273
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Due to a series of special structures and properties, high-entropy alloys (HEAs) have evolved from a new type of alloy design concept to a rising star of high-performance structural materials in just over ten years. Recently, researchers have successively carried out study on the dynamic mechanical behavior and deformation mechanism of HEAs, aiming to promote the practical application, consolidate the theoretical basis and further enrich the connotation of HEAs.
This review offers a retrospection of the research progress of dynamic deformation mechanisms of HEAs. The dislocation movement, twinning deformation, strain-induced phase transformation and adiabatic shear effect of HEAs under dynamic loading are summarized and analyzed. On this basis, it is found that the deformation mechanisms of the HEAs under dynamic loading and quasi-static loading have both interrelated similarities and noteworthy differences. Specifically, HEAs whose dynamic deformation is dominated by dislocation movement are affected by thermal activation mechanism, drag mechanism and strong interaction between dislocations, and exhibit significant strain rate effects, strain sensitivity, and strong strain hardening ability. The dislocation motion under dynamic loading is affected by a series of microstructures such as lattice distortion, short-range orderings, and second phase. In addition, the dynamic deformation behaviors of face centered cubic HEAs with low stacking fault energy, metastable HEAs and refractory HEAs are subject to twinning deformation, strain induced phase transformation, and thermal effect as well as adiabatic shear effect resulting from localization of deformation respectively.
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Study on Strengthening Methods of AlCoCrFeNi High-Entropy Alloys
LI Hongchao, WANG Jun, YUAN Ruihao, WANG Yi, KOU Hongchao, LI Jinshan
Materials Reports
2021,35(17 ):17010 -17018. DOI:10.11896/cldb.21020106
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High-entropy alloys (HEAs) is also called multi-principal element alloys. Compared with traditional alloys with one or two elements as the principal constituents, the multiple constituent elements design concept of HEAs grants them the unique constituent, phase structure and a series of excellent mechanical properties. Especially in recent years, there are a lot of HEAs with high strength and ductility, which is of great significance to their engineering application. The excellent mechanical performance is closely related to the strengthening mechanism of the alloys, such as grain-boundary strengthening, coherent second phase strengthening and heterogeneous structure strengthening mechanism, which all promote the improvement of the performance of HEAs in various degrees. Therefore, it is crucial to understand the strengthening mechanism of the HEAs in order to improve the mechanical properties of the HEAs and explore new high-strength and high-ductility HEAs. AlCoCrFeNi HEAs is currently one of the most studied HEAs, which can produce different structure through composition adjustment and different thermo-mechanical treatment process, thus inducing different strengthening mechanism. The mechanical properties of AlCoCrFeNi HEAs can be adjusted in a wide range, making it an ideal material to study the strengthening mechanism of HEAs. Based on this, this article focuses on the subject of the strengthening mechanism of AlCoCrFeNi HEAs.
In this article, the strengthening mechanism of HEAs in recent years are reviewed, including grain-boundary strengthening, coherent second phase strengthening, incoherent second phase strengthening and heterogeneous structure strengthening. The composition and structure control for HEAs strengthening mechanism and mechanical properties is further expounded. In addition, this paper proposes that the single strengthening mechanism cannot greatly improve the strength of the alloy. By summarizing the multiple strengthening mechanism, it is proposed that the higher strength can be achieved by combining multiple strengthening mechanisms. At last, the future perspective of strengthening mechanism in HEAs is also discussed.
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Research Progress on the Design, Preparation and Properties of High-entropy Metallic Glasses
CHONG Kai, ZHANG Zhibin, ZOU Yong, LIANG Xiubing
Materials Reports
2021,35(17 ):17019 -17025. DOI:10.11896/cldb.20120197
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High-entropy metallic glasses High-entropy metallic glasses are an emerging class of materials that show promising potential forvarious engineering applications because of their advantageous characteristics of high-entropy alloy composition and amorphous alloy structure. Owing to their excellent mechanical and physical properties, these metallic glasses have recently attracted increased attention. Research on related high-entropy metallic glasses is still in its infancy. In this study, the bases for designing the composition of high-entropy metallic glasses are introduced, and the effects of key physical parameters, such as mixing entropy (Δ
S
mix
), mixing enthalpy (Δ
H
mix
), and atomic mismatch (
δ
), on the microstructures of high-entropy metallic glasses are comprehensively analyzed. Moreover, the current status of the study of alloys systems, preparation methods, and mechanical and physical properties is discussed and summarized. Material systems of high-entropy metallic glasses that have been developed remain limited. Current methods for preparing high-entropy metallic glasses have inherited the characteristics of those for preparing amorphous alloys and high-entropy alloys. These methods can be roughly divided into liquid-phase preparation, gas-phase preparation, and solid-phase preparation. Owing to their excellent thermodynamic properties, high-entropy amorphous materials are expected to break through the size limit through thermal spraying and achieve large-scale applications. Research on the properties of high-entropy metallic glasses mainly focuses on mechanical properties, corrosion resistance, magnetic properties, amorphous-forming ability, and thermal stability. Among these topics of interest, the influence of high-entropy on the amorphous formation, structure, thermodynamic properties, and abnormal thermal stability of high-entropy metallic glasses must be urgently resolved. Potential topics on studies of material systems of high-entropy metallic glasses on the basis of the concept of material genetic engineering are explored. The application prospects of such materials are also discussed.
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Effect of C on Microstructure and Mechanical Properties of CoFe
2
NiV
0.5
Mo
0.2
High Entropy Alloy
ZHANG Guojia, LI Ren, LIU Dehua, LU Yiping, WANG Tongmin, LI Tingju
Materials Reports
2021,35(17 ):17026 -17030. DOI:10.11896/cldb.21010131
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Effects of the addition of C with different molar fraction (0%—10%) on microstructure, phase structure and mechanical properties at room temperature of the CoFe
2
NiV
0.5
Mo
0.2
high entropy alloy were investigated. The results show that with the increase of C content, the microstructure of alloy changed from a single face centered cubic structure (FCC) to eutectic structure (FCC matrix+V
8
C
7
carbide fiber) and then to (FCC matrix+coarse V
8
C
7
+acicular MoC). The compressive yield strength of the alloy was improved significantly and remained good ductility simultaneously. When C content is 6%, the yield strength and hardness of the alloy can reach 900 MPa and 270HV respectively. The research results show that elements with small atomic radius represented by C can solubilize as interstitial element or combined with metal element to form carbide second phase, which can improve the FCC-structured high entropy alloy strength, thus optimizing its comprehensive mechanical properties.
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Research Status on the Application of High-entropy Alloys in Dissimilar Metal Welding
WU Zhenggang, LI Xi, LI Zhongtao
Materials Reports
2021,35(17 ):17031 -17036. DOI:10.11896/cldb.21060252
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Manufacturing industry has been pursuing “light-weighting” to reduce energy consumption. Property advantages of different materials can be well merged in a dissimilar metal welds/joints; thus dissimilar metal welding is one of the most effective approaches to achieving “light-weighting”. However, hard and brittle intermetallic compounds (IMCs) tend to form at the welding interfaces and to significantly reduce the strength and toughness of the welds. The formation of interface IMC would be prohibited or even avoided by using high entropy alloys (HEAs) as “interlayer” materials during dissimilar metal welding/joining. This possibility is a result of the synergistic cooperation of HEAs’ high entropy effect and sluggish diffusion effect. Current explorations on the application of HEAs in this area are reviewed in the present paper, focusing on the effects of HEAs on the IMC formation, microstructure and mechanical properties of the joints. Despite the great potential, more fundamental stu-dies are needed to mechanistically understand the effects of HEAs on the microstructure and mechanical properties of different weld interfaces. In addition, studies should be gradually switched from laboratory-scale materials to industry-scale materials to further promote the application.
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Advances of the Strengthening and Toughening of High-entropy Multi-principal-element Heat-resistant Alloys
GAO Niu, LIU Xinwang, WU Weifeng, BAI Zhucheng, YAO Junqing, FAN Zitian
Materials Reports
2021,35(17 ):17037 -17042. DOI:10.11896/cldb.21040085
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Heat-resistant alloys are unique high-temperature materials widely used in the aerospace and shipbuilding industries. However,operating temperatures are now reaching limits posed by the melting temperatures of these materials.Since 2004, a new alloy design philosophy—high-entropy alloy (HEAs) or multi-principle-element alloys (MPEAs) were proposed, which have attracted significant attention due to their excellent mechanical properties, including high strength and high ductility. Due to their superior mechanical performance, HEAs are promising to be deve-loped on heat-resistant alloys. Among them, refractory HEAs with body-centered cubic (BCC) structure exhibit high high-temperature strength but poor room-temperature plasticity, while HEAs with face-centered cubic (FCC) structure show great ductility but low high-temperature strength. A variety of strengthening and toughening methods were conducted for FCC and BCC HEAs, respectively. The present work summarizes the research progress of heat-resistant HEAs. The microstructure evolution and mechanical properties at high temperatures are briefly reviewed. Finally,the future perspective of heat-resistant HEAs is prospected.
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Research Progress of Strategies for Improving Strength-ductility Combinations and Mechanical Properties of High Entropy Alloys
WANG Weitong, CHEN Shuying, ZHANG Yong, ZHAO Yonghao
Materials Reports
2021,35(17 ):17043 -17050. DOI:10.11896/cldb.20080303
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Since the high entropy alloy has been reported for the first time, its excellent mechanical properties have attracted wide attention from all over the world. The superior strength, high hardness, good resistance to wear and corrosion of the high entropy alloy and its excellent service ability at extreme temperatures illustrate that the high entropy alloy has great potential in industrial applications in the future. With the increasing investigation of high entropy alloys, from the variation of elemental types, and the proportion of principal elements, the optimization and development of mechanical properties of high entropy alloys are accompanied by structural changes. Nevertheless, the mechanical properties of high entropy alloys still have much room for improvement. Therefore, how to rationally design the composition and microstructure and enhance the mechanical properties of high entropy alloys is a hot topic at present.
In high entropy alloys, the existing strengthening and toughening methods include fine-grained strengthening, solid solution strengthening and toughening, eutectic structure strengthening and toughening, TWIP (twinning induced plasticity) effect strengthening and toughening, TRIP (transformation induced plasticity) effect strengthening and toughening, and precipitate strengthening and toughening. Fine-grained strengthening and precipitate strengthening exist in most high entropy alloys and it is easy to achieve by thermomechanical treatment. Therefore, how to establish the correlation between the strengthening mechanisms, microstructural characteristics and mechanical properties is a critical issue at present.
In present paper, the research progress of strengthening and toughening methods in high entropy alloys is summarized, and the design concepts of solid solution strengthening, SRO (short-range ordering) strengthening, precipitate strengthening and heterogeneous strengthening and toughening were introduced as well. We also discuss the effect of various special structures on the deformation mechanism and mechanical pro-perties of high entropy alloy. The problems and development prospects of the high entropy alloy in the research process are also analyzed, in order to provide important reference for the subsequent establishment of effective connection between the microstructural characteristics and the mechanical properties.
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The Progress of High-entropy Alloys with the Functional Properties
DU Yuhang, DING Deyu, GUO Ning, GUO Shengfeng
Materials Reports
2021,35(17 ):17051 -17063. DOI:10.11896/cldb.21030186
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For the traditional alloys, most of which were based on a single principal element. They improved the comprehensive properties of the mate-rials always by adding a small or tiny number of specific elements. However, it limited the development of their components and novel pro-perties to a large extent. Therefore, it is high time to develop unconventional alloys to meet the increasing demands. High-entropy alloys (HEAs), a new type of multi-element metals found in recent years, have been gaining increasing popularity among lots of researchers within just these few years because of its unique design concept, organizational structure and excellent properties. Compared with the traditional ones which focused on the boundary (vertex, edge) region of the phase diagram, HEAs attach more importance to the region near the center of the multi-component phase diagram, which is why HEAs have a wider space for the development of composition design. Besides, high-entropy alloys exhibit excellent mechanical properties and good functional properties. Currently, most researches on HEAs focus on the microstructure and mechanical properties of structural materials. According to the composition design and deformation mechanism of HEAs have made great progress. However, the theoretical researches on the functional properties of high-entropy alloys are still very limited. Therefore, this study not only briefly introduces the development of HEAs and systematically summarizes the preparation methods of HEAs, but also discusses the research status of corrosion resis-tance and wear resistance in detail and then summarizes the main factors affecting these properties. In addition, attention has also been paid to the current research status of HEAs as soft magnetic, anti-radiative, catalytic, biomedical materials. Finally, the critical issues of the present research and future development of high-entropy alloys are prospected. The current review would provide the useful reference for scientists who conduct researches on the functional HEAs.
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Research Progress in Refractory High-entropy Alloys
CHEN Gang, LUO Tao, SHEN Shucheng, TAO Tao, TANG Xiaotian, XUE Wei
Materials Reports
2021,35(17 ):17064 -17080. DOI:10.11896/cldb.20070306
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High-entropy alloys (HEAs), also known as multi-principal component solid solution alloys, have attracted widely attention of scholars at home and abroad due to its unique alloy design concepts and excellent comprehensive properties, which have gradually become a research hot spot in the field of metal materials. Refractory high-entropy alloys (RHEAs) are thought to be a new type of superalloys designed and deve-loped based on HEAs of refractory elements. Compared with traditional high-temperature alloys, RHEAs have higher high-temperature strength, high-temperature oxidation resistance and high-temperature phase stability, implicating broad application prospects in the field of aerospace and petrochemical. Since it was proposed in 2010, RHEAs have become an important branch in the research field of HEAs.
So far, 4th, 5th, 6th periods and Ⅳ, Ⅴ, Ⅵ subgroup of 9 elements (Ti, V, Cr, Zr, Nb, Mo, Hf, Ta, W) and additional elements, such as Al, C, Co, Ni, were used as principal component of RHEAs by scholars, and formed a complex alloy system. There are more than 100 alloy systems reported, the phase structure of these alloys ranges from single-phase BCC structure to double-phase, such as BCC1+BCC2, BCC+Laves, etc., and to multi-phase structure, showing structural diversity. The microstructure of RHEAs includes dendrite, equiaxed crystal, eutectic structure or deformation twin structure, etc., and the properties determined by microstructure have its own strong points. The preparation of RHEAs first adopted melting methods, including arc melting and induction melting, which required repeated remelting under high-purity protective gas. In recent years, research has also been conducted on the preparation of RHEAs by powder metallurgy, which has obtained fine particle size and relatively uniform composition. In addition, laser cladding, magnetron sputtering, etc. are also used to prepare materials or coatings for RHEAs. It can be seen that with the deepening of research, RHEAs are constantly making new progress in the research of composition design, preparation process, phase structure and microstructure, room temperature and high temperature performance.
In this review, according to the research status in RHEAs at home and abroad in the past few years, its principal composition, phase structure and preparation method were systematically introduced, and the evolution of RHEAs properties, including density, strength and plasticity, high-temperature oxidation resistance, wear resistance and corrosion resistance, were summarized. Finally, it points out the challenges faced by RHEAs and puts forward suggestions on future research priorities.
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Research Progress on Solid Solution Strengthening of High Entropy Alloys
WEN Cheng, MO Wanwan, TIAN Yuwan, WANG Gui, HU Jiezhen
Materials Reports
2021,35(17 ):17081 -17089. DOI:10.11896/cldb.20070084
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There is no identification of solute and solvent in high entropy alloys, compared to traditional alloy materials. The lattice distortion and size mismatch caused by the special composition of high entropy alloys make it possess significant solid solution strengthening effect, and hence lead to excellent mechanical strength. However, classical strengthening theories based on diluted solute assumption cannot be used to describe the strengthening effect of high entropy alloys, so it is hard to accurately predict the strength of high entropy alloys, which hinders the rational design and application research of such alloys. In recent years, some researchers explore the solid solution strengthening origin and try to develop reliable strengthening models to realize the high-throughput prediction of strength/hardness, and ultimately guide the rapid composition design for performance requirement, to promote the scientific research and engineering application of high entropy alloys. In this review, we summarized the research progress on solid solution strengthening of high entropy alloys, introduced three typical strengthening models at present, compared and analyzed the model construction, prediction effect, remaining problems and the specific application in the design of high entropy alloys. Finally, we prospected the exploration of solid solution strengthening mechanism of high entropy alloys, the development and application of strengthening model.
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High Entropy Alloys(2021)
