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Experimental Mechanics

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23-11-2016

Estimation of Fracture Toughness of Metallic Materials Using Instrumented Indentation: Critical Indentation Stress and Strain Model

Authors: S.-W. Jeon, K.-W. Lee, J. Y. Kim, W. J. Kim, C.-P. Park, D. Kwon

Published in: Experimental Mechanics | Issue 7/2017

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Abstract

We propose a generalized approach based on fracture mechanics and contact mechanics to estimate the fracture toughness in metallic materials from instrumented indentation testing. Models were developed for brittle and ductile fracture. Different criteria were applied to each model to determine the critical fracture point during indentation. For brittle fracture, the critical fracture point was defined in terms of the critical mean pressure; for ductile fracture, the critical fracture point was derived from fracture strain and critical plastic zone size. Each fracture criterion was used to determine the indentation fracture energy corresponding to the fracture energy required for crack extension. The fracture toughness was estimated for various metallic materials using each model and compared with standard fracture toughness tests.

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Title: Estimation of Fracture Toughness of Metallic Materials Using Instrumented Indentation: Critical Indentation Stress and Strain Model
Authors: S.-W. Jeon
K.-W. Lee
J. Y. Kim
W. J. Kim
C.-P. Park
D. Kwon
Publication date: 23-11-2016
Publisher: Springer US
Published in: Experimental Mechanics / Issue 7/2017
Print ISSN: 0014-4851
Electronic ISSN: 1741-2765
DOI: https://doi.org/10.1007/s11340-016-0226-2

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Preface

The Influence of Indenter Tip Imperfection and Deformability on Analysing Instrumented Indentation Tests at Shallow Depths of Penetration on Stiff and Hard Materials

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