David E. Alman scite author profile

There has been considerable technological interest in high-entropy alloys (HEAs) since the initial publications on the topic appeared in 2004. However, only several of the alloys investigated are truly single-phase solid solution compositions. These include the FCC alloys CoCrFeNi and CoCrFeMnNi based on 3d transition metals elements and BCC alloys NbMoTaW, NbMoTaVW, and HfNbTaTiZr based on refractory metals. The search for new single-phase HEAs compositions has been hindered by a lack of an effective scientific strategy for alloy design. This report shows that the chemical interactions and atomic diffusivities predicted from ab initio molecular dynamics simulations which are closely related to primary crystallization during solidification can be used to assist in identifying single phase high-entropy solid solution compositions. Further, combining these simulations with phase diagram calculations via the CALPHAD method and inspection of existing phase diagrams is an effective strategy to accelerate the discovery of new single-phase HEAs. This methodology was used to predict new singlephase HEA compositions. These are FCC alloys comprised of CoFeMnNi, CuNiPdPt and CuNiPdPtRh, and HCP alloys of CoOsReRu.

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Machine-learning informed prediction of high-entropy solid solution formation: Beyond the Hume-Rothery rules

Pei¹,

Yin²,

Hawk³

et al. 2020

npj Comput Mater

155

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The empirical rules for the prediction of solid solution formation proposed so far in the literature usually have very compromised predictability. Some rules with seemingly good predictability were, however, tested using small data sets. Based on an unprecedented large dataset containing 1252 multicomponent alloys, machine-learning methods showed that the formation of solid solutions can be very accurately predicted (93%). The machine-learning results help identify the most important features, such as molar volume, bulk modulus, and melting temperature. As such a new thermodynamics-based rule was developed to predict solid–solution alloys. The new rule is nonetheless slightly less accurate (73%) but has roots in the physical nature of the problem. The new rule is employed to predict solid solutions existing in the three blocks, each of which consists of 9 elements. The predictions encompass face-centered cubic (FCC), body-centered cubic (BCC), and hexagonal closest packed (HCP) structures in a high throughput manner. The validity of the prediction is further confirmed by CALculations of PHAse Diagram (CALPHAD) calculations with high consistency (94%). Since the new thermodynamics-based rule employs only elemental properties, applicability in screening for solid solution high-entropy alloys is straightforward and efficient.

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The effect of manganese additions on the reactive evaporation of chromium in Ni–Cr alloys

2006

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Reactive sintering of TiAl–Ti5Si3 in situ composites

Alman

2005

Intermetallics

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The product that forms upon reactive sintering a mixture of Ti and A1 powders with a composition corresponding to the intennetallic compound TiAl is quite porous. In fact, the density decreases upon sintering and the physical dimensions of the powder compact increase (Le., the specimen swells). The generation of porosity has been attributed to several factors, andKirkendall porosity due to unbalanced diffiisivities. AI diffuses faster in Ti, than does Ti in AI. The result i s a pore in the product where the A1 powder resided prior to the initiation of the reaction.Gus evolution due to the volatization of impurities at the powder surfaces.Commercial Ti powders tend to have a high residual impurity (particularly chloride) content E1 I], and the heat generated by the reaction is sufficient to volatize these

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David E. Alman

Rechargeable magnesium battery: Current status and key challenges for the future

Searching for Next Single-Phase High-Entropy Alloy Compositions

Machine-learning informed prediction of high-entropy solid solution formation: Beyond the Hume-Rothery rules

The effect of manganese additions on the reactive evaporation of chromium in Ni–Cr alloys

Reactive sintering of TiAl–Ti5Si3 in situ composites

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