TY - JOUR
T1 - Formation of nanostructured surface layer, the white layer, through solid particles impingement during slurry erosion in a martensitic medium-carbon steel
AU - Javaheri, V.
AU - Sadeghpour, S.
AU - Karjalainen, P.
AU - Lindroos, Matti
AU - Haiko, O.
AU - Sarmadi, N.
AU - Pallaspuro, S.
AU - Valtonen, K.
AU - Pahlevani, F.
AU - Laukkanen, Anssi
AU - Kömi, J.
N1 - Funding Information:
The authors are grateful for the financial support from the Academy of Finland (#311934 – Genome of Steel Project). The corresponding author would also like to thank Jenny and Antti Wihuri Foundation for the financial support.
Publisher Copyright:
© 2022 The Author(s)
PY - 2022/5/15
Y1 - 2022/5/15
N2 - The extremely altered topmost surface layer, known as the white layer, formed in a medium-carbon low-alloy steel as result of impacts by angular 10–12 mm granite particles during the slurry erosion process is comprehensively investigated. For this purpose, the characteristics, morphology, and formation mechanism of this white layer are described based on the microstructural observations using optical, scanning and transmission electron microscopies as well as nanoindentation hardness measurements and modelling of surface deformation. The white layer exhibits a nanocrystalline structure consisting of ultrafine grains with an average size of 200 nm. It has a nanohardness level of around 10.1 GPa, considerably higher than that of untempered martensitic bulk material (5.7 GPa) achieved by an induction hardening treatment. The results showed that during the high-speed slurry erosion process, solid particle impacts brought forth conditions of high strain, high strain rate, and multi-directional strain paths. This promoted formation of a cell-type structure at first and later, after increasing the number of impacts, development of subgrains following by subgrain rotation and eventually formation of a nanocrystalline structure with ultra-high hardness. The model confirmed that high strain conditions - much higher than required for the onset of plastic deformation - can be achieved on the surface resulting in severe microstructural and property changes during the slurry erosion test.
AB - The extremely altered topmost surface layer, known as the white layer, formed in a medium-carbon low-alloy steel as result of impacts by angular 10–12 mm granite particles during the slurry erosion process is comprehensively investigated. For this purpose, the characteristics, morphology, and formation mechanism of this white layer are described based on the microstructural observations using optical, scanning and transmission electron microscopies as well as nanoindentation hardness measurements and modelling of surface deformation. The white layer exhibits a nanocrystalline structure consisting of ultrafine grains with an average size of 200 nm. It has a nanohardness level of around 10.1 GPa, considerably higher than that of untempered martensitic bulk material (5.7 GPa) achieved by an induction hardening treatment. The results showed that during the high-speed slurry erosion process, solid particle impacts brought forth conditions of high strain, high strain rate, and multi-directional strain paths. This promoted formation of a cell-type structure at first and later, after increasing the number of impacts, development of subgrains following by subgrain rotation and eventually formation of a nanocrystalline structure with ultra-high hardness. The model confirmed that high strain conditions - much higher than required for the onset of plastic deformation - can be achieved on the surface resulting in severe microstructural and property changes during the slurry erosion test.
KW - Cell formation
KW - Martensite deformation
KW - Martensitic steel
KW - Nanocrystalline structure
KW - Nanohardness
KW - Slurry erosion
KW - White layer
UR - http://www.scopus.com/inward/record.url?scp=85125449643&partnerID=8YFLogxK
U2 - 10.1016/j.wear.2022.204301
DO - 10.1016/j.wear.2022.204301
M3 - Article
AN - SCOPUS:85125449643
SN - 0043-1648
VL - 496-497
JO - Wear
JF - Wear
M1 - 204301
ER -