Nanomechanical characterization of alumina coatings grown on FeCrAl alloy by thermal oxidation
Nanomechanical characterization of alumina coatings grown on FeCrAl alloy by thermal oxidation
This work studies the feasibility of using repetitive-nano-impact tests with a cube-corner tip and low loads for obtaining quantitative fracture toughness values in thin and brittle coatings. For this purpose, it will be assumed that the impacts are able to produce a cracking, similar to the pattern developed for the classical fracture toughness tests in bulk materials, and therefore, from the crack developed in the repetitive impacts it will be possible to evaluate the suitability of the classical indentation models (Anstins and Laugier) for measuring fracture toughness. However, the length of this crack has to be lower than 10% of the total coating thickness to avoid substrate contributions. For this reason, and in order to ensure a small plastic region localized at the origin of the crack tip, low load values (or small distance between the indenter tip and the surface) have to be used. In order to demonstrate the validity of this technique, repetitive-nano-impact will be done in a fine and dense oxide layer (α-Al2O3), which has been developed on the top of oxide dispersion strengthened (ODS) FeCrAl alloys (PM 2000) by thermal oxidation at elevated temperatures. Moreover, it will be shown how it is possible to know with each new impact the crack geometry evolution from Palmqvist crack to half-penny crack, being able to study the proper evolution of the different values of fracture toughness in terms of both indentation models and as a function of the strain rate, View the MathML sourceε̇, decreasing. Thereby, fracture toughness values for α-Al2O3 layer decrease from ~4.40 View the MathML sourceMPam , for high View the MathML sourceϵ̇ value (103 s−1), to ~3.21View the MathML sourceMPam, for quasi-static View the MathML sourceϵ̇ value (10−3 s−1). On the other hand, View the MathML sourceϵ̇ a new process to obtain fracture toughness values will be analysed, when the classical indentation models are not met. These values are typically found in the literature for bulk α-Al2O3, demonstrating the use of repetitive-nano-impact tests which not only provide qualitative information about fracture resistance of the materials but it also can be used to obtain quantitative information as fracture toughness values in the case of brittle materials.
310-320
Frutos, E.
8730c6ea-7f59-44b7-aa33-cfee57de8b25
Gonzalez-Carrasco, J.L.
1a1f4550-2c21-468d-8cce-b367b053511b
Polcar, T.
c669b663-3ba9-4e7b-9f97-8ef5655ac6d2
Frutos, E.
8730c6ea-7f59-44b7-aa33-cfee57de8b25
Gonzalez-Carrasco, J.L.
1a1f4550-2c21-468d-8cce-b367b053511b
Polcar, T.
c669b663-3ba9-4e7b-9f97-8ef5655ac6d2
Frutos, E., Gonzalez-Carrasco, J.L. and Polcar, T.
(2016)
Nanomechanical characterization of alumina coatings grown on FeCrAl alloy by thermal oxidation.
Journal of the Mechanical Behavior of Biomedical Materials, 57, .
(doi:10.1016/j.jmbbm.2016.01.027).
Abstract
This work studies the feasibility of using repetitive-nano-impact tests with a cube-corner tip and low loads for obtaining quantitative fracture toughness values in thin and brittle coatings. For this purpose, it will be assumed that the impacts are able to produce a cracking, similar to the pattern developed for the classical fracture toughness tests in bulk materials, and therefore, from the crack developed in the repetitive impacts it will be possible to evaluate the suitability of the classical indentation models (Anstins and Laugier) for measuring fracture toughness. However, the length of this crack has to be lower than 10% of the total coating thickness to avoid substrate contributions. For this reason, and in order to ensure a small plastic region localized at the origin of the crack tip, low load values (or small distance between the indenter tip and the surface) have to be used. In order to demonstrate the validity of this technique, repetitive-nano-impact will be done in a fine and dense oxide layer (α-Al2O3), which has been developed on the top of oxide dispersion strengthened (ODS) FeCrAl alloys (PM 2000) by thermal oxidation at elevated temperatures. Moreover, it will be shown how it is possible to know with each new impact the crack geometry evolution from Palmqvist crack to half-penny crack, being able to study the proper evolution of the different values of fracture toughness in terms of both indentation models and as a function of the strain rate, View the MathML sourceε̇, decreasing. Thereby, fracture toughness values for α-Al2O3 layer decrease from ~4.40 View the MathML sourceMPam , for high View the MathML sourceϵ̇ value (103 s−1), to ~3.21View the MathML sourceMPam, for quasi-static View the MathML sourceϵ̇ value (10−3 s−1). On the other hand, View the MathML sourceϵ̇ a new process to obtain fracture toughness values will be analysed, when the classical indentation models are not met. These values are typically found in the literature for bulk α-Al2O3, demonstrating the use of repetitive-nano-impact tests which not only provide qualitative information about fracture resistance of the materials but it also can be used to obtain quantitative information as fracture toughness values in the case of brittle materials.
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Accepted/In Press date: 25 January 2016
e-pub ahead of print date: 1 February 2016
Organisations:
nCATS Group
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Local EPrints ID: 407706
URI: http://eprints.soton.ac.uk/id/eprint/407706
ISSN: 1751-6161
PURE UUID: 2521d457-f31a-4e1b-a66c-bbe40f824616
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Date deposited: 22 Apr 2017 01:09
Last modified: 16 Mar 2024 04:08
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Author:
E. Frutos
Author:
J.L. Gonzalez-Carrasco
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