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Mark Kortschot
Mark Kortschot
Bestätigte E-Mail-Adresse bei utoronto.ca
Titel
Zitiert von
Zitiert von
Jahr
Cellulose microfibrils: a novel method of preparation using high shear refining and cryocrushing
A Chakraborty, M Sain, M Kortschot
Walter de Gruyter 59 (1), 102-107, 2005
4322005
Processing and characterization of microcellular foamed high‐density polythylene/isotactic polypropylene blends
S Doroudiani, CB Park, MT Kortschot
Polymer Engineering & Science 38 (7), 1205-1215, 1998
3441998
Effect of the crystallinity and morphology on the microcellular foam structure of semicrystalline polymers
S Doroudiani, CB Park, MT Kortschot
Polymer Engineering & Science 36 (21), 2645-2662, 1996
3401996
Predicting the elastic modulus of natural fibre reinforced thermoplastics
AG Facca, MT Kortschot, N Yan
Composites Part A: Applied Science and Manufacturing 37 (10), 1660-1671, 2006
3322006
Predicting the tensile strength of natural fibre reinforced thermoplastics
AG Facca, MT Kortschot, N Yan
Composites Science and Technology 67 (11-12), 2454-2466, 2007
1962007
Damage mechanics of composite materials: I—Measurements of damage and strength
MT Kortschot, PWR Beaumont
Composites Science and Technology 39 (4), 289-301, 1990
1831990
Fabrication and characterization of fully biodegradable natural fiber-reinforced poly (lactic acid) composites
Y Du, T Wu, N Yan, MT Kortschot, R Farnood
Composites Part B: Engineering 56, 717-723, 2014
1692014
Reinforcing potential of wood pulp-derived microfibres in a PVA matrix
A Chakraborty, M Sain, M Kortschot
Walter de Gruyter 60 (1), 53-58, 2006
1382006
The role of the resin fillet in the delamination of honeycomb sandwich structures
R Okada, MT Kortschot
Composites Science and Technology 62 (14), 1811-1819, 2002
922002
Damage mechanics of composite materials: II—a damaged-based notched strength model
MT Kortschot, PWR Beaumont
Composites science and Technology 39 (4), 303-326, 1990
861990
An experimental study of creep behavior of lightweight natural fiber-reinforced polymer composite/honeycomb core sandwich panels
Y Du, N Yan, MT Kortschot
Composite Structures 106, 160-166, 2013
752013
Polystyrene foams. III. Structure–tensile properties relationships
S Doroudiani, MT Kortschot
Journal of applied polymer science 90 (5), 1427-1434, 2003
672003
Mode III delamination using a split cantilever beam
F Sharif, MT Kortschot, RH Martin
ASTM International, 1995
671995
Polystyrene foams. II. Structure–impact properties relationships
S Doroudiani, MT Kortschot
Journal of applied polymer science 90 (5), 1421-1426, 2003
652003
Correction to the Fukuda-Kawata Young's modulus theory and the Fukuda-Chou strength theory for short fibre-reinforced composite materials
K Jayaraman, MT Kortschot
Journal of materials science 31 (8), 2059-2064, 1996
651996
Computer simulation of the electrical conductivity of polymer composites containing metallic fillers
MT Kortschot, RT Woodhams
Polymer composites 9 (1), 60-71, 1988
631988
Polystyrene foams. I. Processing‐structure relationships
S Doroudiani, MT Kortschot
Journal of Applied Polymer Science 90 (5), 1412-1420, 2003
602003
Damage mechanics of composite materials. III: Prediction of damage growth and notched strength
MT Kortschot, PWR Beaumont, MF Ashby
Composites Science and Technology 40 (2), 147-165, 1991
601991
Light-weight honeycomb core sandwich panels containing biofiber-reinforced thermoset polymer composite skins: Fabrication and evaluation
Y Du, N Yan, MT Kortschot
Composites Part B: Engineering 43 (7), 2875-2882, 2012
572012
Expanded wood fiber polystyrene composites: processing–structure–mechanical properties relationships
S Doroudiani, MT Kortschot
Journal of Thermoplastic Composite Materials 17 (1), 13-30, 2004
562004
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