Machine learning in nuclear materials research

IF 12.2 2区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY
Dane Morgan , Ghanshyam Pilania , Adrien Couet , Blas P. Uberuaga , Cheng Sun , Ju Li
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引用次数: 29

Abstract

Nuclear materials are often demanded to function for extended time in extreme environments, including high radiation fluxes with associated transmutations, high temperature and temperature gradients, mechanical stresses, and corrosive coolants. They also have a wide range of microstructural and chemical makeups, resulting in multifaceted and often out-of-equilibrium interactions. Machine learning (ML) is increasingly being used to tackle these complex time-dependent interactions and aid researchers in developing models and making predictions, sometimes with better accuracy than traditional modeling that focuses on one or two parameters at a time. Conventional practices of acquiring new experimental data in nuclear materials research are often slow and expensive, limiting the opportunity for data-centric ML, but new methods are changing that paradigm. Here we review high-throughput computational and experimental data approaches, especially robotic experimentation and active learning that is based on Gaussian process and Bayesian optimization. We show ML examples in structural materials (e.g., reactor pressure vessel (RPV) alloys and radiation detecting scintillating materials) and highlight new techniques of high-throughput sample preparation and characterizations, and automated radiation/environmental exposures and real-time online diagnostics. This review suggests that ML models of material constitutive relations in plasticity, damage, and even electronic and optical responses to radiation are likely to become powerful tools as they develop. Finally, we speculate on how the recent trends of using natural language processing (NLP) to aid the collection and analysis of literature data, interpretable artificial intelligence (AI), and the use of streamlined scripting, database, workflow management, and cloud computing platforms that will soon make the utilization of ML techniques as commonplace as the spreadsheet curve-fitting practices of today.

Abstract Image

核材料研究中的机器学习
通常要求核材料在极端环境下长时间工作,包括伴随嬗变的高辐射通量、高温和温度梯度、机械应力和腐蚀性冷却剂。它们还具有广泛的微观结构和化学组成,导致多方面和经常不平衡的相互作用。机器学习(ML)越来越多地被用于解决这些复杂的时间依赖性相互作用,并帮助研究人员开发模型和做出预测,有时比一次只关注一两个参数的传统建模更准确。在核材料研究中获取新实验数据的传统做法通常是缓慢而昂贵的,限制了以数据为中心的机器学习的机会,但新方法正在改变这种模式。在这里,我们回顾了高通量的计算和实验数据方法,特别是基于高斯过程和贝叶斯优化的机器人实验和主动学习。我们展示了结构材料(例如,反应堆压力容器(RPV)合金和辐射检测闪烁材料)中的ML示例,并重点介绍了高通量样品制备和表征,自动化辐射/环境暴露和实时在线诊断的新技术。这篇综述表明,随着材料本构关系的发展,塑性、损伤甚至辐射的电子和光学响应的ML模型可能会成为强大的工具。最后,我们推测了最近使用自然语言处理(NLP)来帮助收集和分析文献数据、可解释的人工智能(AI)以及使用流线型脚本、数据库、工作流管理和云计算平台的趋势,这些趋势将很快使ML技术的利用像今天的电子表格曲线拟合实践一样普遍。
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来源期刊
Current Opinion in Solid State & Materials Science
Current Opinion in Solid State & Materials Science 工程技术-材料科学:综合
CiteScore
21.10
自引率
3.60%
发文量
41
审稿时长
47 days
期刊介绍: Title: Current Opinion in Solid State & Materials Science Journal Overview: Aims to provide a snapshot of the latest research and advances in materials science Publishes six issues per year, each containing reviews covering exciting and developing areas of materials science Each issue comprises 2-3 sections of reviews commissioned by international researchers who are experts in their fields Provides materials scientists with the opportunity to stay informed about current developments in their own and related areas of research Promotes cross-fertilization of ideas across an increasingly interdisciplinary field
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