Design of high-strength refractory complex solid-solution alloys

Design of high-strength refractory complex solid-solution alloys

Nickel-based superalloys and near-equiatomic high-entropy alloys containing molybdenum are known for higher temperature strength and corrosion resistance. Yet, complex solid-solution alloys offer a huge design space to tune for optimal properties at slightly reduced entropy. For refractory Mo-W-Ta-T...

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Bibliographic Details
Published in:npj computational materials Vol. 4; no. 1; pp. 1 - 8
Main Authors: Singh, Prashant, Sharma, Aayush, Smirnov, A. V., Diallo, Mouhamad S., Ray, Pratik K., Balasubramanian, Ganesh, Johnson, Duane D.
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 28-03-2018
Nature Publishing Group
Subjects:
639/301/1023/1026
639/301/1023/303
639/301/1034/1037
639/301/1034/1038
639/301/119/995
Alloys
Approximation
Characterization and Evaluation of Materials
Chemistry and Materials Science
Coherent potential approximation
Computational Intelligence
Computer simulation
Corrosion resistance
Corrosion resistant alloys
Deformation
Dynamic stability
Electronic properties
Electronic structure
Enthalpy
Entropy
High entropy alloys
High strength alloys
Identification methods
MATERIALS SCIENCE
Mathematical and Computational Engineering
Mathematical and Computational Physics
Mathematical Modeling and Industrial Mathematics
Mechanical properties
Modulus of elasticity
Molybdenum
Nickel
Nickel base alloys
Short range order
Superalloys
Theoretical
Titanium
Zirconium
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Summary:Nickel-based superalloys and near-equiatomic high-entropy alloys containing molybdenum are known for higher temperature strength and corrosion resistance. Yet, complex solid-solution alloys offer a huge design space to tune for optimal properties at slightly reduced entropy. For refractory Mo-W-Ta-Ti-Zr, we showcase KKR electronic structure methods via the coherent-potential approximation to identify alloys over five-dimensional design space with improved mechanical properties and necessary global (formation enthalpy) and local (short-range order) stability. Deformation is modeled with classical molecular dynamic simulations, validated from our first-principle data. We predict complex solid-solution alloys of improved stability with greatly enhanced modulus of elasticity (3× at 300 K) over near-equiatomic cases, as validated experimentally, and with higher moduli above 500 K over commercial alloys (2.3× at 2000 K). We also show that optimal complex solid-solution alloys are not described well by classical potentials due to critical electronic effects. Solid solutions: screening by electronic structure Combining first-principle calculations with electronic alloy design criteria lead to the identification of desirable complex alloys. A team led by Duane Johnson at Iowa State University, USA, applied density functional theory to explore the design space formed by five refractory elements (molybdenum, tungsten, tantalum, titanium, and zirconium) and identified optimal molybdenum-rich alloy compositions for high temperature strength and corrosion resistance. By predicting structural properties such as the Young’s modulus as well as the short-range atomic order, a lattice constant identified the global stability of each composition and allowed for the fast screening of the design space to select the best compositions. Both molecular dynamics and experimental testing confirmed the predicted mechanical properties. This electronic structure approach can help optimize complex solution alloys for enhanced mechanical properties.
Bibliography:USDOE
AC02-07CH11358
IS-J 9459; IS-J 9579
ISSN:2057-3960
2057-3960
DOI:10.1038/s41524-018-0072-0