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深度传感压痕法的扩展应用

Extended Applications of the Depth-Sensing Indentation Method.

作者信息

Olasz Dániel, Lendvai János, Szállás Attila, Gulyás Gábor, Chinh Nguyen Q

机构信息

Department of Materials Physics, Eötvös Loránd University, P.O.B. 32, H-1518 Budapest, Hungary.

SEMILAB Semiconductor Physics Laboratory Co. Ltd., Prielle Kornélia u. 4/a., H-1117 Budapest, Hungary.

出版信息

Micromachines (Basel). 2020 Nov 23;11(11):1023. doi: 10.3390/mi11111023.

DOI:10.3390/mi11111023
PMID:33238504
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7700657/
Abstract

The depth-sensing indentation method has been applied for almost 30 years. In this review, a survey of several extended applications developed during the last three decades is provided. In depth-sensing indentation measurements, the load and penetration depth data are detected as a function of time, in most cases at controlled loading rates. Therefore, beside the determination of hardness and Young's modulus, different deformation mechanisms and many other dynamic characteristics and phenomena, such as the dynamic elastic modulus, load-induced phase transition, strain rate sensitivity, etc. can be studied. These extended applications of depth-sensing indentation measurements are briefly described and reviewed.

摘要

深度传感压痕法已经应用了近30年。在这篇综述中,对过去三十年中开发的几种扩展应用进行了调查。在深度传感压痕测量中,载荷和压入深度数据是作为时间的函数来检测的,在大多数情况下是在控制加载速率下进行的。因此,除了测定硬度和杨氏模量外,还可以研究不同的变形机制以及许多其他动态特性和现象,如动态弹性模量、载荷诱导相变、应变速率敏感性等。本文简要描述并综述了深度传感压痕测量的这些扩展应用。

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本文引用的文献

1
Dynamic nanoindentation testing: is there an influence on a material's hardness?动态纳米压痕测试:对材料硬度有影响吗?
Mater Res Lett. 2017 Nov 3;5(7):486-493. doi: 10.1080/21663831.2017.1331384. eCollection 2017 Nov.
2
Advanced Nanoindentation Testing for Studying Strain-Rate Sensitivity and Activation Volume.
JOM (1989). 2017;69(11):2246-2255. doi: 10.1007/s11837-017-2536-y. Epub 2017 Aug 28.
3
Micro-Mechanical Response of an Al-Mg Hybrid System Synthesized by High-Pressure Torsion.通过高压扭转合成的铝镁混合体系的微观力学响应
Materials (Basel). 2017 May 30;10(6):596. doi: 10.3390/ma10060596.
4
Thickness-dependent phase transformation in nanoindented germanium thin films.纳米压痕锗薄膜中与厚度相关的相变
Nanotechnology. 2008 Nov 26;19(47):475709. doi: 10.1088/0957-4484/19/47/475709. Epub 2008 Oct 30.
5
Scale-free intermittent flow in crystal plasticity.晶体塑性中的无标度间歇流
Science. 2006 May 26;312(5777):1188-90. doi: 10.1126/science.1123889.
6
Sample dimensions influence strength and crystal plasticity.试样尺寸会影响强度和晶体可塑性。
Science. 2004 Aug 13;305(5686):986-9. doi: 10.1126/science.1098993.
7
Nanocrystallization during nanoindentation of a bulk amorphous metal alloy at room temperature.室温下块状非晶态金属合金纳米压痕过程中的纳米晶化。
Science. 2002 Jan 25;295(5555):654-7. doi: 10.1126/science.1067453.