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Damage evolution in freeze cast metal/ceramic composites exhibiting lamellar microstructures

Authors :
C. Simpson
P.J. Withers
T. Lowe
S. Roy
A. Wanner
Source :
Fracture and Structural Integrity, Vol 9, Iss 33, Pp 134-142 (2015)
Publication Year :
2015
Publisher :
Gruppo Italiano Frattura, 2015.

Abstract

The damage evolution in a single domain aluminium/alumina freeze-cast composite has been examined using 3D X-ray computed tomography (CT). A single domain was extracted and loaded incrementally at an orientation of 45° to the lamellae, with the damage being assessed after each of eight compressive loading steps. Prior to loading, significant damage was observed at the metal-ceramic interface – this is thought to have formed during machining and can be ascribed to weak interfacial bonding associated with the Cu coating applied to the ceramic preform prior to metal infiltration. Further interfacial damage was seen to initiate after loading to 170MPa and to develop with each subsequent load step. Damage was also observed in the ceramic lamellae, with a series of parallel cracks forming across the alumina, perpendicular to the domain orientation. These sets of parallel, intra-lamellae cracks were closely spaced, but initiated independently, with coalescence only occurring at higher loads. Both the interfacial and intra-lamellae cracking initiated after loading to 170MPa, with the intra-lamellae cracks propagating into the metal matrix after loading to 240MPa. The cracks in the ceramic lamellae were found to form and develop independent of the interfacial cracks, with discrete crack paths and morphologies being observed in each case. Despite this, the underlying driving force was the same for each damage mode, with crack propagation being driven by an elastic-plastic mismatch between the metal matrix and ceramic lamellae.

Details

Language :
English
ISSN :
19718993
Volume :
9
Issue :
33
Database :
Directory of Open Access Journals
Journal :
Fracture and Structural Integrity
Publication Type :
Academic Journal
Accession number :
edsdoj.56e3a5186fed476f97eb65d4cef1999d
Document Type :
article
Full Text :
https://doi.org/10.3221/IGF-ESIS.33.17