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Autori principali: Hegde, Vinay I., Peterson, Miroslava, Allec, Sarah I., Lu, Xiaonan, Mahadevan, Thiruvillamalai, Nguyen, Thanh, Kalahe, Jayani, Oshiro, Jared, Seffens, Robert J., Nickerson, Ethan K., Du, Jincheng, Riley, Brian J., Vienna, John D., Saal, James E.
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2405.09897
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author Hegde, Vinay I.
Peterson, Miroslava
Allec, Sarah I.
Lu, Xiaonan
Mahadevan, Thiruvillamalai
Nguyen, Thanh
Kalahe, Jayani
Oshiro, Jared
Seffens, Robert J.
Nickerson, Ethan K.
Du, Jincheng
Riley, Brian J.
Vienna, John D.
Saal, James E.
author_facet Hegde, Vinay I.
Peterson, Miroslava
Allec, Sarah I.
Lu, Xiaonan
Mahadevan, Thiruvillamalai
Nguyen, Thanh
Kalahe, Jayani
Oshiro, Jared
Seffens, Robert J.
Nickerson, Ethan K.
Du, Jincheng
Riley, Brian J.
Vienna, John D.
Saal, James E.
contents Informatics-driven approaches, such as machine learning and sequential experimental design, have shown the potential to drastically impact next-generation materials discovery and design. In this perspective, we present a few guiding principles for applying informatics-based methods towards the design of novel nuclear waste forms. We advocate for adopting a system design approach, and describe the effective usage of data-driven methods in every stage of such a design process. We demonstrate how this approach can optimally leverage physics-based simulations, machine learning surrogates, and experimental synthesis and characterization, within a feedback-driven closed-loop sequential learning framework. We discuss the importance of incorporating domain knowledge into the representation of materials, the construction and curation of datasets, the development of predictive property models, and the design and execution of experiments. We illustrate the application of this approach by successfully designing and validating Na- and Nd-containing phosphate-based ceramic waste forms. Finally, we discuss open challenges in such informatics-driven workflows and present an outlook for their widespread application for the cleanup of nuclear wastes.
format Preprint
id arxiv_https___arxiv_org_abs_2405_09897
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Towards Informatics-Driven Design of Nuclear Waste Forms
Hegde, Vinay I.
Peterson, Miroslava
Allec, Sarah I.
Lu, Xiaonan
Mahadevan, Thiruvillamalai
Nguyen, Thanh
Kalahe, Jayani
Oshiro, Jared
Seffens, Robert J.
Nickerson, Ethan K.
Du, Jincheng
Riley, Brian J.
Vienna, John D.
Saal, James E.
Materials Science
Informatics-driven approaches, such as machine learning and sequential experimental design, have shown the potential to drastically impact next-generation materials discovery and design. In this perspective, we present a few guiding principles for applying informatics-based methods towards the design of novel nuclear waste forms. We advocate for adopting a system design approach, and describe the effective usage of data-driven methods in every stage of such a design process. We demonstrate how this approach can optimally leverage physics-based simulations, machine learning surrogates, and experimental synthesis and characterization, within a feedback-driven closed-loop sequential learning framework. We discuss the importance of incorporating domain knowledge into the representation of materials, the construction and curation of datasets, the development of predictive property models, and the design and execution of experiments. We illustrate the application of this approach by successfully designing and validating Na- and Nd-containing phosphate-based ceramic waste forms. Finally, we discuss open challenges in such informatics-driven workflows and present an outlook for their widespread application for the cleanup of nuclear wastes.
title Towards Informatics-Driven Design of Nuclear Waste Forms
topic Materials Science
url https://arxiv.org/abs/2405.09897