Add to ORKGLow-carbon low-alloyed ferritic steels are the main material for the production of high-strength pipes for the transportation of oil and gas. The formation of brittle carbide network during the lifetime of a pipeline could be a reason for a catastrophic failure. Among other reasons, it can be controlled by the morphology of grain boundary (GB) carbides. The microstructure of a low-alloyed ferritic steel containing 0.09 at.% C and small amounts of Si, Mn, Nb, Cu, Al, Ni, and Cr was studied between 300 and 900 A degrees C. The samples were annealed very long time (700 to 4000 h) in order to produce the equilibrium morphology of phases. The (alpha-Fe)/(alpha-Fe) GBs can be either completely or incompletely wetted (covered) by the gamma-Fe (aus...
We performed a three-dimensional (3D) analysis of ferrite grains recrystallized in low-carbon steel ...
The attainment of finer ferrite grain structure in low carbon is object of interest because sig-nifi...
Low carbon steel. The resulting microstructure is therefore virtually all of the ferrite phase, sinc...
Grain size refinement is one of the most efficient strengthening mechanisms applied to modern High-S...
Grain boundaries (GBs), particularly ferrite: ferrite GBs, of X70 pipeline steel were characterized ...
The effect of prior-austenite grain size (PAGS) on bainitic ferrite (BF) morphology and effective gr...
A systematic survey of morphology of bainite and proeutectoid ferrite was carried out in order to va...
Analytical electron microscopy was used to characterise grain boundaries (GBs) and interphase bounda...
Low carbon steel with a microstructure consisting mostly of ferrite with the darker pearlite regions...
The microstructural evolution of submicron sized ferrite in bimodal structural ultrafine grained fer...
Medium carbon steel with a microstructure consisting mostly of ferrite with the darker pearlite regi...
The attainment of finer ferrite grain structure in low carbon is object of interest because signific...
The microstructural evolution of a Fe-Mn-Al-Ni-C low-density steel was studied. The lightweight low-...
The rate of bainite formation depends on several factors such as austenite grain size, decomposition...
The microstructural evolution of a Fe-Mn-Al-Ni-C low-density steel was studied. The lightweight low-...
We performed a three-dimensional (3D) analysis of ferrite grains recrystallized in low-carbon steel ...
The attainment of finer ferrite grain structure in low carbon is object of interest because sig-nifi...
Low carbon steel. The resulting microstructure is therefore virtually all of the ferrite phase, sinc...
Grain size refinement is one of the most efficient strengthening mechanisms applied to modern High-S...
Grain boundaries (GBs), particularly ferrite: ferrite GBs, of X70 pipeline steel were characterized ...
The effect of prior-austenite grain size (PAGS) on bainitic ferrite (BF) morphology and effective gr...
A systematic survey of morphology of bainite and proeutectoid ferrite was carried out in order to va...
Analytical electron microscopy was used to characterise grain boundaries (GBs) and interphase bounda...
Low carbon steel with a microstructure consisting mostly of ferrite with the darker pearlite regions...
The microstructural evolution of submicron sized ferrite in bimodal structural ultrafine grained fer...
Medium carbon steel with a microstructure consisting mostly of ferrite with the darker pearlite regi...
The attainment of finer ferrite grain structure in low carbon is object of interest because signific...
The microstructural evolution of a Fe-Mn-Al-Ni-C low-density steel was studied. The lightweight low-...
The rate of bainite formation depends on several factors such as austenite grain size, decomposition...
The microstructural evolution of a Fe-Mn-Al-Ni-C low-density steel was studied. The lightweight low-...
We performed a three-dimensional (3D) analysis of ferrite grains recrystallized in low-carbon steel ...
The attainment of finer ferrite grain structure in low carbon is object of interest because sig-nifi...
Low carbon steel. The resulting microstructure is therefore virtually all of the ferrite phase, sinc...