Design of Light-Weight High-Entropy Alloys

Feng, Rui; Gao, Michael C.; Lee, Chanho; Mathes, Michael; Zuo, Tingting; Chen, Shu Ying; Hawk, Jeffrey A.; Zhang, Yong; Liaw, Peter K.

doi:10.3390/e18090333

Cited by 178 publications

(64 citation statements)

References 52 publications

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“…Thus, there are many corresponding calculation methods, the first-principles density functional theory (DFT), molecular dynamics (MD), discrete dislocation dynamics (DDD), phase-field method (PFM), thermodynamics model (TM), finite element method (FEM) [111], etc. For materials with different space scales, there are corresponding material calculation methods, including the calculation of phase diagram (CALPHAD) and high-throughput methods [26,65,69,[112][113][114][115][116][117].…”

Section: Heas and "Materials Genome Initiative"mentioning

confidence: 99%

“…Although the DFT has many simplifications of the Schrӧdinger equation, the computational process is still challenging due to the HEAs containing multiple principal components. Thus, hybrid Monte Carlo/molecular dynamics (MC/ MD) simulations, ab initio molecular dynamics (AIMD) simulations, special quasi-random structure (SQS) modeling, coherent potential approximation (CPA), even small sets of ordered structures (SSOS) calculations are used for the DFT calculation of HEAs [24,40,59,116,[129][130][131][132][133][134][135]. REVIEW .…”

Section: Dft Computationsmentioning

confidence: 99%

“…However, if such data are not available unfortunately, it becomes necessary to design and carry out experiments. In this regard, the thermodynamic data obtained from the DFT calculations will be useful to fill up experimental data [31,116]. Thus, the reliable thermodynamic databases, containing a series of functions related to the composition and temperature, are assessed by the CALPHAD method, based on the reliable experimental data and accurate DFT results [40,50,[113][114][115][116][117][119][120][121][122].…”

Section: Calphad Modelingmentioning

confidence: 99%

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Science and technology in high-entropy alloys

2018

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As human improve their ability to fabricate materials, alloys have evolved from simple to complex compositions, accordingly improving functions and performances, promoting the advancements of human civilization. In recent years, high-entropy alloys (HEAs) have attracted tremendous attention in various fields. With multiple principal components, they inherently possess unique microstructures and many impressive properties, such as high strength and hardness, excellent corrosion resistance, thermal stability, fatigue, fracture, and irradiation resistance, in terms of which they overwhelm the traditional alloys. All these properties have endowed HEAs with many promising potential applications. An in-depth understanding of the essence of HEAs is important to further developing numerous HEAs with better properties and performance in the future. In this paper, we review the recent development of HEAs, and summarize their preparation methods, composition design, phase formation and microstructures, various properties, and modeling and simulation calculations. In addition, the future trends and prospects of HEAs are put forward.

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Section: Heas and "Materials Genome Initiative"mentioning

confidence: 99%

Section: Dft Computationsmentioning

confidence: 99%

Section: Calphad Modelingmentioning

confidence: 99%

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Science and technology in high-entropy alloys

2018

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“…5,9 Moreover, the formation of FCC-or BCC-type HEAs in a given multicomponent system can be estimated by the value of the VEC, i.e., VEC > 7.5~8 and VEC < 6~7.5 for FCC and BCC HEAs, respectively,. 5,9,11,17 Recently, a new approach has been established to accelerate the exploration of multicomponent alloys with solid-solution phases by combining calculated phase diagrams with simple rules based on the phases present, transformation temperatures, and attendant microstructures, 7 which introduces a technique to predict and achieve target properties (e.g., strength, modulus, and phase stabilities). 8,18,19 In the present work, we will describe and discuss the atomic and electronic foundations for the VEC-categorized and based principles in FCC or BCC HEAs.…”

Section: Introductionmentioning

confidence: 99%

Atomic and electronic basis for the serrations of refractory high-entropy alloys

et al. 2017

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Refractory high-entropy alloys present attractive mechanical properties, i.e., high yield strength and fracture toughness, making them potential candidates for structural applications. Understandings of atomic and electronic interactions are important to reveal the origins for the formation of high-entropy alloys and their structure−dominated mechanical properties, thus enabling the development of a predictive approach for rapidly designing advanced materials. Here, we report the atomic and electronic basis for the valence−electron-concentration-categorized principles and the observed serration behavior in high-entropy alloys and highentropy metallic glass, including MoNbTaW, MoNbVW, MoTaVW, HfNbTiZr, and Vitreloy-1 MG (Zr 41 Ti 14 Cu 12.5 Ni 10 Be 22.5 ). We find that the yield strengths of high-entropy alloys and high-entropy metallic glass are a power-law function of the electron-work function, which is dominated by local atomic arrangements. Further, a reliance on the bonding-charge density provides a groundbreaking insight into the nature of loosely bonded spots in materials. The presence of strongly bonded clusters and weakly bonded glue atoms imply a serrated deformation of high-entropy alloys, resulting in intermittent avalanches of defects movement.

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“…To meet the challenges, computational methods are indispensable. Different computational approaches, ranging from empirical rules [6,7] to semi-empirical CAL-PHAD method, [8][9][10][11][12] and to theoretical first principles method, [13,14] have been applied for screening of HEAs. For example, many empirical rules in terms of mixing enthalpy, configurational entropy, atomic size mismatch, valence electron concentration and their various combinations, have been proposed and tested to explore potential HEAs of simple solid solutions.…”

Section: Introductionmentioning

confidence: 99%

TCHEA1: A Thermodynamic Database Not Limited for “High Entropy” Alloys

Mao

Chen²,

Chen³

2017

J. Phase Equilib. Diffus.

119

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In this paper we report a thermodynamic database which was developed by using the CALPHAD approach. The TCHEA1 database includes 15 chemical elements (Al, Co, Cr, Cu, Fe, Hf, Mn, Mo, Nb, Ni, Ta, Ti, V, W and Zr). It is suitable for the study of Bcc and Fcc HEA systems. The database is constructed based on the thermodynamic assessment of all binary systems and many key ternary systems where almost all possible metastable and stable phases are considered. It is extensively demonstrated in the present work that TCHEA1 gives satisfactory prediction on the phase equilibria in various HEA systems (quaternary to ennead) and wide temperature ranges (liquidus to subsolidus). Thermodynamic stability calculations of simple solid solutions (Bcc and Fcc) and intermetallics (sigma, Laves, l-phase etc.) are validated against the available experimental information in as-cast or as-annealed state. Such CALPHAD database focusing on the modelling of Gibbs energy rather than entropy makes reliable predictions of thermodynamic equilibrium and phase transformation, no matter whether the alloy/system has high entropy or not. Cases with miscibility gap in liquid and solid solutions and second-order phase transition at low temperatures are demonstrated. With the volume data included, TCHEA1 is capable to predict the density and thermal expansion coefficient of HEAs as well. This thermodynamic database is also applicable in process simulations when used together with compatible kinetic databases.

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Design of Light-Weight High-Entropy Alloys

Cited by 178 publications

References 52 publications

Science and technology in high-entropy alloys

Science and technology in high-entropy alloys

Atomic and electronic basis for the serrations of refractory high-entropy alloys

TCHEA1: A Thermodynamic Database Not Limited for “High Entropy” Alloys

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