O.N. Senkov scite author profile

Abstract:We develop a strategy to design and evaluate high-entropy alloys (HEAs) for structural use in the transportation and energy industries. We give HEA goal properties for low (≤150 °C), medium (≤450 °C) and high (≥1,100 °C) use temperatures. A systematic design approach uses palettes of elements chosen to meet target properties of each HEA family and gives methods to build HEAs from these palettes. We show that intermetallic phases are consistent with HEA definitions, and the strategy developed here includes both single-phase, solid solution HEAs and HEAs with intentional addition of a 2nd phase for particulate hardening. A thermodynamic estimate of the effectiveness of configurational entropy to suppress or delay compound formation is given. A 3-stage approach is given to systematically screen and evaluate a vast number of HEAs by integrating high-throughput computations and experiments. CALPHAD methods are used to predict phase equilibria, and high-throughput experiments on materials libraries with controlled composition and microstructure gradients are suggested. Much of this evaluation can be done now, but key components (materials libraries with microstructure gradients and high-throughput tensile testing) are currently missing. Suggestions for future HEA efforts are given.

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The influence of efficient atomic packing on the constitution of metallic glasses

Miracle

Sanders

Senkov

2003

Philosophical Magazine

421

297

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Accelerated exploration of multi-principal element alloys with solid solution phases

et al. 2015

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Recent multi-principal element, high entropy alloy (HEA) development strategies vastly expand the number of candidate alloy systems, but also pose a new challenge-how to rapidly screen thousands of candidate alloy systems for targeted properties. Here we develop a new approach to rapidly assess structural metals by combining calculated phase diagrams with simple rules based on the phases present, their transformation temperatures and useful microstructures. We evaluate over 130,000 alloy systems, identifying promising compositions for more time-intensive experimental studies. We find the surprising result that solid solution alloys become less likely as the number of alloy elements increases. This contradicts the major premise of HEAs-that increased configurational entropy increases the stability of disordered solid solution phases. As the number of elements increases, the configurational entropy rises slowly while the probability of at least one pair of elements favouring formation of intermetallic compounds increases more rapidly, explaining this apparent contradiction.

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Microstructure and elevated temperature properties of a refractory TaNbHfZrTi alloy

et al. 2012

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O.N. Senkov

A critical review of high entropy alloys and related concepts

Mechanical properties of Nb25Mo25Ta25W25 and V20Nb20Mo20Ta20W20 refractory high entropy alloys

Development and exploration of refractory high entropy alloys—A review

Microstructure and room temperature properties of a high-entropy TaNbHfZrTi alloy

Exploration and Development of High Entropy Alloys for Structural Applications

The influence of efficient atomic packing on the constitution of metallic glasses

Accelerated exploration of multi-principal element alloys with solid solution phases

Microstructure and elevated temperature properties of a refractory TaNbHfZrTi alloy

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