新型生物启发氧化铝牙科复合材料弯曲行为的微机械建模。

IF 4.6 1区 医学 Q1 DENTISTRY, ORAL SURGERY & MEDICINE
Urangua Jargalsaikhan , Hongbo Wan , Nathanael Leung , Xu Song , Jianan Hu , Bo Su , Tan Sui
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引用次数: 0

摘要

牙冠陶瓷的临床失效模式涉及界面的径向开裂,由陶瓷层在次表面的挠曲产生的表面张力驱动。这导致大多数全陶瓷牙冠的使用寿命缩短。因此,研究最佳材料组合以减少牙冠材料中的应力集中已成为未来成功临床应用的关键。天然材料(如珍珠质)的各向异性复杂结构有可能创造出合适的高强度抗损伤材料。它们在宏观和微观层面上对天然结构优化和机械功能的模仿可最大限度地减少牙冠的弱点。本研究旨在优化具有成本效益的冷冻铸造生物启发复合材料,以制造新型、坚固和韧性强的陶瓷基牙冠。为此,对含有四种不同聚合物相的多层氧化铝(Al2O3)复合材料进行了测试,以评估其弯曲行为并确定其抗弯强度。根据实验结果开发并验证了一个计算模型。该模型包括 Al2O3 层,这些层会受到温和的压缩并分散应力,而聚合物层则充当应力释放器,发生塑性变形以减少应力集中。根据实验数据和数值建模得出的结论是,这些复合材料的机械性能存在差异,这主要是由于微观结构和抗弯强度不同造成的。此外,研究结果表明,基于 Al2O3 的生物启发复合材料具有良好的变形和强化性能,有望应用于牙科领域。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Micromechanical modelling for bending behaviour of novel bioinspired alumina-based dental composites

The clinical failure mode of dental crown ceramics involves radial cracking at the interface, driven by the surface tension generated from the flexure of the ceramic layer on the subsurface. This results in a reduced lifespan for most all-ceramic dental crowns. Therefore, investigating optimal material combinations to reduce stress concentration in dental crown materials has become crucial for future successful clinical applications. The anisotropic complex structures of natural materials, such as nacre, could potentially create suitable strong and damage-resistant materials. Their imitation of natural structural optimisation and mechanical functionality at both the macro- and micro-levels minimises weaknesses in dental crowns. This research aims to optimise cost-effective, freeze-casted bioinspired composites for the manufacture of novel, strong, and tough ceramic-based dental crowns. To this end, multilayer alumina (Al2O3) composites with four different polymer phases were tested to evaluate their bending behaviour and determine their flexural strength. A computational model was developed and validated against the experimental results. This model includes Al2O3 layers that undergo gentle compression and distribute stress, while the polymer layers act as stress relievers, undergoing plastic deformation to reduce stress concentration. Based on the experimental data and numerical modelling, it was concluded that these composites exhibit variability in mechanical properties, primarily due to differences in microstructures and their flexural strength. Furthermore, the findings suggest that bioinspired Al2O3-based composites demonstrate promising deformation and strengthening behaviour, indicating potential for application in the dental field.

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来源期刊
Dental Materials
Dental Materials 工程技术-材料科学:生物材料
CiteScore
9.80
自引率
10.00%
发文量
290
审稿时长
67 days
期刊介绍: Dental Materials publishes original research, review articles, and short communications. Academy of Dental Materials members click here to register for free access to Dental Materials online. The principal aim of Dental Materials is to promote rapid communication of scientific information between academia, industry, and the dental practitioner. Original Manuscripts on clinical and laboratory research of basic and applied character which focus on the properties or performance of dental materials or the reaction of host tissues to materials are given priority publication. Other acceptable topics include application technology in clinical dentistry and dental laboratory technology. Comprehensive reviews and editorial commentaries on pertinent subjects will be considered.
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