Modeling dislocation dynamics data using semantic web technologies.

IF 4.5 3区计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Neural Computing & Applications Pub Date : 2025-01-01 Epub Date: 2024-12-14 DOI:10.1007/s00521-024-10674-5

Ahmad Zainul Ihsan, Said Fathalla, Stefan Sandfeld

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引用次数: 0

Abstract

The research in Materials Science and Engineering focuses on the design, synthesis, properties, and performance of materials. An important class of materials that is widely investigated are crystalline materials, including metals and semiconductors. Crystalline material typically contains a specific type of defect called "dislocation". This defect significantly affects various material properties, including bending strength, fracture toughness, and ductility. Researchers have devoted a significant effort in recent years to understanding dislocation behaviour through experimental characterization techniques and simulations, e.g., dislocation dynamics simulations. This paper presents how data from dislocation dynamics simulations can be modelled using semantic web technologies through annotating data with ontologies. We extend the dislocation ontology by adding missing concepts and aligning it with two other domain-related ontologies (i.e., the Elementary Multi-perspective Material Ontology and the Materials Design Ontology), allowing for efficiently representing the dislocation simulation data. Moreover, we present a real-world use case for representing the discrete dislocation dynamics data as a knowledge graph (DisLocKG) which can depict the relationship between them. We also developed a SPARQL endpoint that brings extensive flexibility for querying DisLocKG.

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基于语义web技术的错位动力学数据建模。

材料科学与工程专业主要研究材料的设计、合成、性能和性能。被广泛研究的一类重要材料是晶体材料，包括金属和半导体。晶体材料通常含有一种称为“位错”的特殊缺陷。该缺陷显著影响各种材料性能，包括抗弯强度、断裂韧性和延展性。近年来，研究人员通过实验表征技术和模拟（例如位错动力学模拟）来理解位错行为。本文介绍了如何使用语义网技术通过用本体注释数据来对错位动力学模拟数据进行建模。我们通过添加缺失概念并将其与其他两个领域相关的本体（即基本多角度材料本体和材料设计本体）对齐来扩展位错本体，从而有效地表示位错模拟数据。此外，我们提出了将离散位错动力学数据表示为知识图（DisLocKG）的实际用例，该知识图可以描述它们之间的关系。我们还开发了一个SPARQL端点，它为查询DisLocKG带来了广泛的灵活性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Neural Computing & Applications 工程技术-计算机：人工智能

CiteScore

11.40

自引率

8.30%

发文量

1280

审稿时长

6.9 months

期刊介绍： Neural Computing & Applications is an international journal which publishes original research and other information in the field of practical applications of neural computing and related techniques such as genetic algorithms, fuzzy logic and neuro-fuzzy systems. All items relevant to building practical systems are within its scope, including but not limited to: -adaptive computing- algorithms- applicable neural networks theory- applied statistics- architectures- artificial intelligence- benchmarks- case histories of innovative applications- fuzzy logic- genetic algorithms- hardware implementations- hybrid intelligent systems- intelligent agents- intelligent control systems- intelligent diagnostics- intelligent forecasting- machine learning- neural networks- neuro-fuzzy systems- pattern recognition- performance measures- self-learning systems- software simulations- supervised and unsupervised learning methods- system engineering and integration. Featured contributions fall into several categories: Original Articles, Review Articles, Book Reviews and Announcements.