Effect of layer thickness on the mechanical behavior of oxidation-strengthened Zr/Nb nanoscale multilayers
Effect of layer thickness on the mechanical behavior of oxidation-strengthened Zr/Nb nanoscale multilayers
The effect of bilayer thickness (L) reduction on the oxidation-induced strengthening of Zr/Nb nanoscale metallic multilayers (NMM) is investigated. Zr/Nb NMMs with L = 10 and 75 nm were annealed at 350 °C for a time ranging between 2 and 336 h, and the changes in structure and deformation behaviour were studied by nanoscale mechanical testing and analytical electron microscopy. Annealing led to the transformation of the Zr layers into ZrO2 after a few hours, while the Nb layers oxidised progressively at a much slower rate. The sequential oxidation of Zr and Nb layers was found to be key for the oxidation to take place without rupture of the multilayered structure and without coating spallation in all cases. However, the multilayers with the smallest bilayer thickness (L = 10 nm) presented superior damage tolerance and therefore structural integrity during the oxidation process, while for L = 75 nm the volumetric expansion associated with oxidation led to the formation of cracks at the interfaces and within the ZrO2 layers. As a result, the nanoindentation hardness increase after annealing was significantly higher for the nanolaminate with L = 10 nm. Comparison between nanoindentation and micropillar compression behaviour of the oxidised NMMs demonstrates that the hardness increase upon oxidation arises from the contribution of the residual stresses associated with the volume increase due to oxidation and to the higher strength of the oxides.
layer, thickness, mechanical beha, oxidation-strengthened, Zr/Nb, nanoscale, multilayers
5860-5878
Monclus, M.A.
eab76faa-a2c2-444f-91a2-40248b78d35f
Callisti, M.
86e03724-aacc-46d5-bccc-4c7025556667
Polcar, T.
c669b663-3ba9-4e7b-9f97-8ef5655ac6d2
Yang, L.W.
c5a2bc84-075b-4a8a-b457-282c4e2c0416
Molina-Aldareguia, J.M.
f4d7ff0d-2b62-4d10-a5dc-9f7acca97064
Llorca, J
339c8796-ee69-4f3c-ac5f-8e56177e4882
April 2018
Monclus, M.A.
eab76faa-a2c2-444f-91a2-40248b78d35f
Callisti, M.
86e03724-aacc-46d5-bccc-4c7025556667
Polcar, T.
c669b663-3ba9-4e7b-9f97-8ef5655ac6d2
Yang, L.W.
c5a2bc84-075b-4a8a-b457-282c4e2c0416
Molina-Aldareguia, J.M.
f4d7ff0d-2b62-4d10-a5dc-9f7acca97064
Llorca, J
339c8796-ee69-4f3c-ac5f-8e56177e4882
Monclus, M.A., Callisti, M., Polcar, T., Yang, L.W., Molina-Aldareguia, J.M. and Llorca, J
(2018)
Effect of layer thickness on the mechanical behavior of oxidation-strengthened Zr/Nb nanoscale multilayers.
Journal of Materials Science, 53 (8), .
(doi:10.1007/s10853-017-1665-6).
Abstract
The effect of bilayer thickness (L) reduction on the oxidation-induced strengthening of Zr/Nb nanoscale metallic multilayers (NMM) is investigated. Zr/Nb NMMs with L = 10 and 75 nm were annealed at 350 °C for a time ranging between 2 and 336 h, and the changes in structure and deformation behaviour were studied by nanoscale mechanical testing and analytical electron microscopy. Annealing led to the transformation of the Zr layers into ZrO2 after a few hours, while the Nb layers oxidised progressively at a much slower rate. The sequential oxidation of Zr and Nb layers was found to be key for the oxidation to take place without rupture of the multilayered structure and without coating spallation in all cases. However, the multilayers with the smallest bilayer thickness (L = 10 nm) presented superior damage tolerance and therefore structural integrity during the oxidation process, while for L = 75 nm the volumetric expansion associated with oxidation led to the formation of cracks at the interfaces and within the ZrO2 layers. As a result, the nanoindentation hardness increase after annealing was significantly higher for the nanolaminate with L = 10 nm. Comparison between nanoindentation and micropillar compression behaviour of the oxidised NMMs demonstrates that the hardness increase upon oxidation arises from the contribution of the residual stresses associated with the volume increase due to oxidation and to the higher strength of the oxides.
Text
paper oxidation pillars Zr-Nb
- Accepted Manuscript
More information
Accepted/In Press date: 5 October 2017
e-pub ahead of print date: 17 October 2017
Published date: April 2018
Keywords:
layer, thickness, mechanical beha, oxidation-strengthened, Zr/Nb, nanoscale, multilayers
Identifiers
Local EPrints ID: 415579
URI: http://eprints.soton.ac.uk/id/eprint/415579
ISSN: 0022-2461
PURE UUID: 51b0d620-b16a-4c80-b207-5d7d1acd83a3
Catalogue record
Date deposited: 15 Nov 2017 17:30
Last modified: 16 Mar 2024 05:55
Export record
Altmetrics
Contributors
Author:
M.A. Monclus
Author:
M. Callisti
Author:
L.W. Yang
Author:
J.M. Molina-Aldareguia
Author:
J Llorca
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
