The effects of subsurface deformation on the sliding wear behaviour of a microtextured high-nitrogen steel surface

“…Available literature [4,5,12,13] also showed the increase in hardness of the deformed surface layer and the appearance of the nano-crystallized microstructure under worn surface after friction testing [4,5]. TEM observation on the slid SUS 304 stainless steel specimens also revealed the co-existence of (i) frictioninduced ␣ and (ii) some level of denser dislocations [12,13]. These phenomena are, to certain extent, verified by the testing results presented in Figs.…”

“…8 and 9 confirmed that the volume fraction of transformed ␥ on the wear trace surface, as similar to the transformation tendency under tensile or compress condition [1], increased with the pressure [8]. Available literature [4,5,12,13] also showed the increase in hardness of the deformed surface layer and the appearance of the nano-crystallized microstructure under worn surface after friction testing [4,5]. TEM observation on the slid SUS 304 stainless steel specimens also revealed the co-existence of (i) frictioninduced ␣ and (ii) some level of denser dislocations [12,13].…”

Friction and wear behavior of SUS 304 austenitic stainless steel against Al2O3 ceramic ball under relative high load

“…Available literature [4,5,12,13] also showed the increase in hardness of the deformed surface layer and the appearance of the nano-crystallized microstructure under worn surface after friction testing [4,5]. TEM observation on the slid SUS 304 stainless steel specimens also revealed the co-existence of (i) frictioninduced ␣ and (ii) some level of denser dislocations [12,13]. These phenomena are, to certain extent, verified by the testing results presented in Figs.…”

“…8 and 9 confirmed that the volume fraction of transformed ␥ on the wear trace surface, as similar to the transformation tendency under tensile or compress condition [1], increased with the pressure [8]. Available literature [4,5,12,13] also showed the increase in hardness of the deformed surface layer and the appearance of the nano-crystallized microstructure under worn surface after friction testing [4,5]. TEM observation on the slid SUS 304 stainless steel specimens also revealed the co-existence of (i) frictioninduced ␣ and (ii) some level of denser dislocations [12,13].…”

Friction and wear behavior of SUS 304 austenitic stainless steel against Al2O3 ceramic ball under relative high load

“…TEM investigations were performed under an accelerating voltage of 120 kV after a sample thickness of less than 100 nm had been reached. In a recent study with worn high‐nitrogen steel samples, this technique did not introduce artefacts into the surface 22…”

Wear mechanisms in metal-on-metal bearings: The importance of tribochemical reaction layers

“…The estimated strain and strain rate during erosion lie in the range of (0.1-1) and (10 3 -10 6 ) s −1 . The high localized strain and strain rate during erosion and abrasion have been observed to develop deformed structure with features like scattered dislocations, dislocation cell structure, deformation bands and grain fragments [13][14][15][16]. The developed structural features precisely manipulate the properties controlling work hardening rate, induce plasticity and toughness [11,12].…”

Microstructural developments during erosion of tribological steels