A novel molecular dynamics approach to simulate micromechanical behavior in characteristic crystallographic planes of transparent alumina ceramics

A novel molecular dynamics approach to simulate micromechanical behavior in characteristic crystallographic planes of transparent alumina ceramics

To investigate the anisotropic properties of brittle-prone transparent alumina ceramics (TACs) and guide the optimized design of material modification, this study employed a novel molecular dynamics (MD) approach to reproduce and analyze the anisotropic micromechanical behaviors of TACs during nanoi...

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Bibliographic Details
Main Authors: Jiajun Chen, Meiqing Guo, Shaoying Zhang, Xinyue Wang, Xingming Zhu, Zhenhua Song, Zhiqiang Li
Format: Article
Language:English
Published: Elsevier 2025-07-01
Series:Journal of Materials Research and Technology
Subjects:
Transparent alumina ceramics
Micromechanical properties
Nanoindentation experiment
Crack observation
Molecular dynamics simulation
Model optimization and enhancement
Online Access:http://www.sciencedirect.com/science/article/pii/S2238785425016874
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Summary:To investigate the anisotropic properties of brittle-prone transparent alumina ceramics (TACs) and guide the optimized design of material modification, this study employed a novel molecular dynamics (MD) approach to reproduce and analyze the anisotropic micromechanical behaviors of TACs during nanoindentation experiments, with a focus on industrially prevalent A-plane {11 2‾ 0} and C-plane (0001) configurations (denoted as TACs-A and TACs-C, respectively). Nanoindentation experiments and morphological observations revealed distinct failure mechanisms: TACs-C exhibited preferential plastic failure characteristics (i.e., displacement pop-in events) during early indentation stages, whereas TACs-A demonstrated intense plasticity-dominated failure in mid-to-late stages due to superior hardness and elastic modulus, ultimately forming radial-intercrossed crack networks. The MD model incorporating the Embedded Atom Method (EAM) potential successfully replicated experimental phenomena. Critical findings include an HCP-to-FCC phase transformation of O atoms in TACs-A during indentation, dominated by Shockley 1/6<112> and Hirth 1/3<100> dislocations that impede slip motion, thereby enhancing mechanical properties and contributing to higher hardness/elastic modulus. Concurrently, dislocation analysis elucidated the early-stage displacement pop-in events in TACs-C: rapid dislocation proliferation (0–5 Å penetration depth) induced localized stress concentration and abrupt displacement. Finally, two optimization strategies (doping modification and graphene atomic coating) were proposed, providing computational modeling support for TACs material design.
ISSN:2238-7854

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