TY - JOUR
T1 - Full-field characterisation of oxide-oxide ceramic-matrix composites using X-ray computed micro-tomography and digital volume correlation under load at high temperatures
AU - Forna Kreutzer, Joachim
AU - Ell, Jon
AU - S. Barnard, Harold
AU - Pirzada, Talha J.
AU - Robert O., Ritchie
AU - Liu, Lilly
PY - 2021/10
Y1 - 2021/10
N2 - In situ synchrotron X-ray computed micro-tomography and digital volume correlation (DVC) were utilised to understand the failure mechanisms at room temperature and 1050 °C of two NextelTM720/alumina oxide-oxide ceramic-matrix composites (CMCs), termed materials A and B, sintered respectively at 1200 °C and ∼1250 °C. At both test temperatures, three-point-bending strengths were ∼55-58 MPa for material A and ∼94-100 MPa for material B. Damage was associated with three primary types of cracking modes: interfacial delamination, inclined cracks within fibre tows, opening of existing matrix shrinkage cracks. Material A exhibited higher shrinkage cracking, whereas material B displayed more pronounced diagonal matrix microcracking. At 1050 °C, both systems showed less microcracking but more pronounced delamination. Such damage characteristics were rationalised in terms of the corresponding 3D DVC displacement/strain fields. Specifically, global DVC was utilised and maximum principal strain locations prior to failure, which varied from 0.005 to 0.01, correlated well to the fracture initiation sites. Further, abrupt positive to negative transitions of shear strain components were observed and were attributed to the different bonding strengths between 0°/90° fibres and the matrix. The current study demonstrates that in situ high-temperature tomography/DVC is a powerful method for studying the deformation and fracture of oxide-oxide CMCs.
AB - In situ synchrotron X-ray computed micro-tomography and digital volume correlation (DVC) were utilised to understand the failure mechanisms at room temperature and 1050 °C of two NextelTM720/alumina oxide-oxide ceramic-matrix composites (CMCs), termed materials A and B, sintered respectively at 1200 °C and ∼1250 °C. At both test temperatures, three-point-bending strengths were ∼55-58 MPa for material A and ∼94-100 MPa for material B. Damage was associated with three primary types of cracking modes: interfacial delamination, inclined cracks within fibre tows, opening of existing matrix shrinkage cracks. Material A exhibited higher shrinkage cracking, whereas material B displayed more pronounced diagonal matrix microcracking. At 1050 °C, both systems showed less microcracking but more pronounced delamination. Such damage characteristics were rationalised in terms of the corresponding 3D DVC displacement/strain fields. Specifically, global DVC was utilised and maximum principal strain locations prior to failure, which varied from 0.005 to 0.01, correlated well to the fracture initiation sites. Further, abrupt positive to negative transitions of shear strain components were observed and were attributed to the different bonding strengths between 0°/90° fibres and the matrix. The current study demonstrates that in situ high-temperature tomography/DVC is a powerful method for studying the deformation and fracture of oxide-oxide CMCs.
KW - Oxide-oxide ceramic-matrix composites
KW - In situ full-field characterisation
KW - High-temperature X-ray computed micro-tomography
KW - Digital volume correlation
KW - Deformation and fracture
U2 - 10.1016/j.matdes.2021.109899
DO - 10.1016/j.matdes.2021.109899
M3 - Article (Academic Journal)
SN - 0261-3069
VL - 208
JO - Materials and Design
JF - Materials and Design
M1 - 109899
ER -