Multi-objective optimization of High-entropy alloy properties
ORAL
Abstract
Body-centered cubic (bcc) high-entropy alloys possess high strength retention at high temperatures, while suffering
from limited ductility and embrittlement at low temperatures. Although both the strength and the ductility
can be characterized by numerical modeling from first principles, the search for a composition with an optimal trade-off is hampered by the complex alloy structure
and vast composition space. In this work, we present a methodology for exploring Pareto-optimal compositions by combining ab initio
based computational workflow with a Bayesian multi-objective optimization framework. One part of the computational workflow involves
evaluation of solid solution strengthening within a model relying on parameters derived from efficient ab initio calculations using
coherent-potential approximation and taking into account finite-temperature and exchange-correlation corrections for the equilibrium volume.
Another part of the workflow is based on a ductility model whose parameters are obtained
using machined-learned interatomic potentials parameterized on the fly by means of
active learning from ab initio calculations.
We demonstrate how our approach can be used to address the strength-ductility trade-off in multi-component alloys
based on refractory metals.
from limited ductility and embrittlement at low temperatures. Although both the strength and the ductility
can be characterized by numerical modeling from first principles, the search for a composition with an optimal trade-off is hampered by the complex alloy structure
and vast composition space. In this work, we present a methodology for exploring Pareto-optimal compositions by combining ab initio
based computational workflow with a Bayesian multi-objective optimization framework. One part of the computational workflow involves
evaluation of solid solution strengthening within a model relying on parameters derived from efficient ab initio calculations using
coherent-potential approximation and taking into account finite-temperature and exchange-correlation corrections for the equilibrium volume.
Another part of the workflow is based on a ductility model whose parameters are obtained
using machined-learned interatomic potentials parameterized on the fly by means of
active learning from ab initio calculations.
We demonstrate how our approach can be used to address the strength-ductility trade-off in multi-component alloys
based on refractory metals.
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Publication: F. Moitzi, L. Romaner, A.V. Ruban, O.E. Peil, Accurate ab initio modeling of solid solution strengthening in high entropy alloys, accepted in Phys. Rev. Mater.<br><br>I Novikov, O Kovalyova, A Shapeev, M Hodapp, AI-accelerated materials informatics method for the discovery of ductile alloys, Journal of Materials Research, 1-14
Presenters
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Franco Moitzi
Materials Center Leoben Forschung GmbH (
Authors
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Franco Moitzi
Materials Center Leoben Forschung GmbH (
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Oleg E Peil
Materials Center Leoben Forschung GmbH
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Max Hodapp
Materials Center Leoben Forschung GmbH
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Lorenz Romaner
University of Leoben