TY - JOUR
T1 - On the strength of grain and phase boundaries in ferritic-martensitic dual-phase steels
AU - Tsipouridis, Prodromos
AU - Koll, Lisa
AU - Krempaszky, Christian
AU - Werner, Ewald
PY - 2011
Y1 - 2011
N2 - Ultramicrohardness of ferrite was thoroughly studied in a low-alloyed ferritic-martensitic dual-phase steel. A series of targeted indents in coarse ferrite grains (in the as-quenched state) enabled the establishment of relationships between the hardness and the distance of the indent from grain or phase boundaries. As expected, the type and the number of boundaries in the vicinity of the indent play a catalytic role to the measured hardness. The increase in the Vickers hardness with appoaching the grain boundaries was attributed to the impediment of dislocation slip due to the boundary obstacle(s). The presence of ferrite/martensite phase boundaries introduces an additional and even more critical effect, i.e. the work-hardened ferrite grains due to the geometrically necessary dislocations associated with the martensitic transformation taking place during the production process. Transmission electron microscopy and electron backscatter diffraction studies on ferrite grains helped to identify the latter effect and provided valuable information about the misorientation and strain state of the grains before and after indentation.
AB - Ultramicrohardness of ferrite was thoroughly studied in a low-alloyed ferritic-martensitic dual-phase steel. A series of targeted indents in coarse ferrite grains (in the as-quenched state) enabled the establishment of relationships between the hardness and the distance of the indent from grain or phase boundaries. As expected, the type and the number of boundaries in the vicinity of the indent play a catalytic role to the measured hardness. The increase in the Vickers hardness with appoaching the grain boundaries was attributed to the impediment of dislocation slip due to the boundary obstacle(s). The presence of ferrite/martensite phase boundaries introduces an additional and even more critical effect, i.e. the work-hardened ferrite grains due to the geometrically necessary dislocations associated with the martensitic transformation taking place during the production process. Transmission electron microscopy and electron backscatter diffraction studies on ferrite grains helped to identify the latter effect and provided valuable information about the misorientation and strain state of the grains before and after indentation.
KW - Coarse-grained DP-steel
KW - Geometrically necessary dislocations (GNDs)
KW - Martensitic transformation
KW - Phase and grain boundaries
KW - Ultramicrohardness
UR - http://www.scopus.com/inward/record.url?scp=79959934743&partnerID=8YFLogxK
U2 - 10.3139/146.110519
DO - 10.3139/146.110519
M3 - Article
AN - SCOPUS:79959934743
SN - 1862-5282
VL - 102
SP - 674
EP - 686
JO - International Journal of Materials Research
JF - International Journal of Materials Research
IS - 6
ER -