$The fracture energy of metal fibre reinforced ceramic composites (MFCs)$
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The fracture energy of metal fibre reinforced ceramic composites (MFCs)

A model is presented for prediction of the fracture energy of ceramic–matrix composites containing dispersed metallic fibres. It is assumed that the work of fracture comes entirely from pull-out and/or plastic deformation of fibres bridging the crack plane. Comparisons are presented between these pr...

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Published in:	Composites science and technology Vol. 71; no. 3; pp. 266 - 275
Main Authors:	Pemberton, S.R., Oberg, E.K., Dean, J., Tsarouchas, D., Markaki, A.E., Marston, L., Clyne, T.W.
Format:	Journal Article
Language:	English
Published:	Kidlington Elsevier Ltd 07-02-2011 Elsevier
Subjects:	A. Ceramic–matrix composites (CMCs) A. Short-fibre composites B. Fibre/matrix bond B. Fracture toughness C. Modelling Ceramic fibers Ceramics Cross-disciplinary physics: materials science; rheology Exact sciences and technology Fibers Fibres Fracture mechanics Fracture toughness Materials science Mathematical models Other materials Physics Plastic deformation Specific materials A. Short-fibre composites B. Fracture toughness C. Modelling A. Ceramic–matrix composites (CMCs) B. Fibre/matrix bond Ceramic matrix composite Short fiber Experimental test A. Ceramic-matrix composites (CMCs) Fiber reinforced material Aluminosilicates Theoretical study Mechanical properties Stainless steels Oxide ceramics Optimization Fracture toughness Metal fiber Composite materials Steel fiber Modelling Alumina Fracture energy Fracture mode
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Abstract	A model is presented for prediction of the fracture energy of ceramic–matrix composites containing dispersed metallic fibres. It is assumed that the work of fracture comes entirely from pull-out and/or plastic deformation of fibres bridging the crack plane. Comparisons are presented between these predictions and experimental measurements made on a commercially-available composite material of this type, containing stainless steel (304) fibres in a matrix predominantly comprising alumina and alumino-silicate phases. Good agreement is observed, and it’s noted that there is scope for the fracture energy levels to be high (∼20 kJ m −2). Higher toughness levels are both predicted and observed for coarser fibres, up to a practical limit for the fibre diameter of the order of 0.5 mm. Other deductions are also made concerning strategies for optimisation of the toughness of this type of material.
AbstractList	A model is presented for prediction of the fracture energy of ceramic-matrix composites containing dispersed metallic fibres. It is assumed that the work of fracture comes entirely from pull-out and/or plastic deformation of fibres bridging the crack plane. Comparisons are presented between these predictions and experimental measurements made on a commercially-available composite material of this type, containing stainless steel (304) fibres in a matrix predominantly comprising alumina and alumino-silicate phases. Good agreement is observed, and it's noted that there is scope for the fracture energy levels to be high (20 kJ m super(-2)). Higher toughness levels are both predicted and observed for coarser fibres, up to a practical limit for the fibre diameter of the order of 0.5 mm. Other deductions are also made concerning strategies for optimisation of the toughness of this type of material. A model is presented for prediction of the fracture energy of ceramic–matrix composites containing dispersed metallic fibres. It is assumed that the work of fracture comes entirely from pull-out and/or plastic deformation of fibres bridging the crack plane. Comparisons are presented between these predictions and experimental measurements made on a commercially-available composite material of this type, containing stainless steel (304) fibres in a matrix predominantly comprising alumina and alumino-silicate phases. Good agreement is observed, and it’s noted that there is scope for the fracture energy levels to be high (∼20 kJ m −2). Higher toughness levels are both predicted and observed for coarser fibres, up to a practical limit for the fibre diameter of the order of 0.5 mm. Other deductions are also made concerning strategies for optimisation of the toughness of this type of material.
Author	Oberg, E.K. Tsarouchas, D. Clyne, T.W. Marston, L. Pemberton, S.R. Dean, J. Markaki, A.E.
Author_xml	– sequence: 1 givenname: S.R. surname: Pemberton fullname: Pemberton, S.R. organization: Department of Materials Science & Metallurgy, Cambridge University, Pembroke Street, Cambridge CB2 3QZ, UK – sequence: 2 givenname: E.K. surname: Oberg fullname: Oberg, E.K. organization: Department of Materials Science & Metallurgy, Cambridge University, Pembroke Street, Cambridge CB2 3QZ, UK – sequence: 3 givenname: J. surname: Dean fullname: Dean, J. organization: Department of Materials Science & Metallurgy, Cambridge University, Pembroke Street, Cambridge CB2 3QZ, UK – sequence: 4 givenname: D. surname: Tsarouchas fullname: Tsarouchas, D. organization: Department of Engineering, Cambridge University, Trumpington Street, Cambridge CB2 1PZ, UK – sequence: 5 givenname: A.E. surname: Markaki fullname: Markaki, A.E. organization: Department of Engineering, Cambridge University, Trumpington Street, Cambridge CB2 1PZ, UK – sequence: 6 givenname: L. surname: Marston fullname: Marston, L. organization: Fibrestone Products Ltd., Brookhill Road, Pinxton, Nottingham NG16 6NT, UK – sequence: 7 givenname: T.W. surname: Clyne fullname: Clyne, T.W. email: twc10@cam.ac.uk organization: Department of Materials Science & Metallurgy, Cambridge University, Pembroke Street, Cambridge CB2 3QZ, UK
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Keywords	A. Short-fibre composites B. Fracture toughness C. Modelling A. Ceramic–matrix composites (CMCs) B. Fibre/matrix bond Ceramic matrix composite Short fiber Experimental test A. Ceramic-matrix composites (CMCs) Fiber reinforced material Aluminosilicates Theoretical study Mechanical properties Stainless steels Oxide ceramics Optimization Fracture toughness Metal fiber Composite materials Steel fiber Modelling Alumina Fracture energy Fracture mode
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Snippet	A model is presented for prediction of the fracture energy of ceramic–matrix composites containing dispersed metallic fibres. It is assumed that the work of... A model is presented for prediction of the fracture energy of ceramic-matrix composites containing dispersed metallic fibres. It is assumed that the work of...
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SubjectTerms	A. Ceramic–matrix composites (CMCs) A. Short-fibre composites B. Fibre/matrix bond B. Fracture toughness C. Modelling Ceramic fibers Ceramics Cross-disciplinary physics: materials science; rheology Exact sciences and technology Fibers Fibres Fracture mechanics Fracture toughness Materials science Mathematical models Other materials Physics Plastic deformation Specific materials
Title	The fracture energy of metal fibre reinforced ceramic composites (MFCs)
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