Generative deep learning as a tool for inverse design of high entropy refractory alloys

Arindam Debnath; Adam M. Krajewski; Hui Sun; Shuang Lin; Marcia Ahn; Wenjie Li; Shanshank Priya; Jogender Singh; Shunli Shang; Allison M. Beese; Zi-Kui Liu; Wesley F. Reinhart

doi:10.20517/jmi.2021.05

Generative deep learning as a tool for inverse design of high entropy refractory alloys

Arindam Debnath
, Adam M. Krajewski
, Hui Sun
, Shuang Lin
, Marcia Ahn
, Wenjie Li
, Shanshank Priya
, Jogender Singh
, Shunli Shang
, Allison M. Beese
, Zi-Kui Liu
, Wesley F. Reinhart

Biochemistry, Chemistry & Physics

Research output: Contribution to journal › Article › peer-review

Abstract

Generative deep learning is powering a wave of new innovations in materials design. This article discusses the basic operating principles of these methods and their advantages over rational design through the lens of a case study on refractory high-entropy alloys for ultra-high-temperature applications. We present our computational infrastructure and workflow for the inverse design of new alloys powered by these methods. Our preliminary results show that generative models can learn complex relationships to generate novelty on demand, making them a valuable tool for materials informatics.

Original language	Undefined/Unknown
Journal	Journal of Materials Informatics
DOIs	https://doi.org/10.20517/jmi.2021.05
State	Published - Sep 2 2021

Keywords

High entropy alloys
databases
machine learning
Inverse design

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10.20517/jmi.2021.05License: CC BY

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abstract = "Generative deep learning is powering a wave of new innovations in materials design. This article discusses the basic operating principles of these methods and their advantages over rational design through the lens of a case study on refractory high-entropy alloys for ultra-high-temperature applications. We present our computational infrastructure and workflow for the inverse design of new alloys powered by these methods. Our preliminary results show that generative models can learn complex relationships to generate novelty on demand, making them a valuable tool for materials informatics. ",

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AU - Debnath, Arindam

AU - Krajewski, Adam M.

AU - Sun, Hui

AU - Lin, Shuang

AU - Ahn, Marcia

AU - Li, Wenjie

AU - Priya, Shanshank

AU - Singh, Jogender

AU - Shang, Shunli

AU - Beese, Allison M.

AU - Liu, Zi-Kui

AU - Reinhart, Wesley F.

PY - 2021/9/2

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N2 - Generative deep learning is powering a wave of new innovations in materials design. This article discusses the basic operating principles of these methods and their advantages over rational design through the lens of a case study on refractory high-entropy alloys for ultra-high-temperature applications. We present our computational infrastructure and workflow for the inverse design of new alloys powered by these methods. Our preliminary results show that generative models can learn complex relationships to generate novelty on demand, making them a valuable tool for materials informatics.

AB - Generative deep learning is powering a wave of new innovations in materials design. This article discusses the basic operating principles of these methods and their advantages over rational design through the lens of a case study on refractory high-entropy alloys for ultra-high-temperature applications. We present our computational infrastructure and workflow for the inverse design of new alloys powered by these methods. Our preliminary results show that generative models can learn complex relationships to generate novelty on demand, making them a valuable tool for materials informatics.

KW - High entropy alloys

KW - databases

KW - machine learning

KW - Inverse design

UR - https://www.oaepublish.com/articles/jmi.2021.05

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DO - 10.20517/jmi.2021.05

M3 - Article

JO - Journal of Materials Informatics

JF - Journal of Materials Informatics

ER -

Generative deep learning as a tool for inverse design of high entropy refractory alloys

Abstract

Keywords

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