Subsurface Microstructure Evolution of Hadfield Steel under High Impact Energy

Yun Hua Xu; Liang Fang; Qihong Cen; Jin Hua Zhu

doi:10.4028/www.scientific.net/MSF.475-479.117

Paper Titles

TEM Observation on Nano-Precipitation of Plain Low Carbon Steel by CSP
p.101

Strain-Induced Precipitation of Nb(CN) during Deformation of Undercooled Austenite in Nb-Microalloyed HSLA Steels
p.105

Distribution of Mo at Grain Boundary of 1300MPa CrMo Steel
p.109

The Mechanism of Intragranular Ferrite Nucleation on Inclusion in Steel
p.113

Subsurface Microstructure Evolution of Hadfield Steel under High Impact Energy
p.117

Evolution of Microstructures in a Low Carbon Bainitic Steel during Reheating
p.121

Dislocation-Precipitate Interaction and Its Effect on Thermostability of Bainite in a Nb-Bearing Steel
p.125

The Aging Behavior for Low Carbon Bainitic Steel Bearing Cu-Nb
p.129

Surface Nanocrystallization of Low Carbon Steel Induced by Circulation Rolling Plastic Deformation
p.133

HomeMaterials Science ForumMaterials Science Forum Vols. 475-479Subsurface Microstructure Evolution of Hadfield...

Subsurface Microstructure Evolution of Hadfield Steel under High Impact Energy

Abstract:

It has been well known that Hadfield steel behaviors excellent wear resistance under high impact energy. Up to now there exist many theories to explain the wear mechanism of Hadfield steel. In this research subsurface microstructure evolution process of Hadfield steel was investigated after high energy impact experiments. It was shown from high resolution electron microscope (HRTEM) examination of subsurface microstructure that nanocrystallized austenite grains have been formed in the procedure of the reaction and rearrangement of high density dislocations under the heavy plastic deformation, sub-grains as a transitional structure and, finally, the formation of nano austenite grains. On the other side, the interactions of twins and stack faults or dislocations and stack faults make austenite crystals transform to amorphous solid. With increasing impact cycles the sizes of nano-grains were decreased and the amorphous volumes were increased further. A large amount of nano-sized grains embedded in bulk amorphous matrix were fully developed, which will dominate the wear of the steel. In the subsurface no martensitic transformation was observed.