Grain refinement of 2Mn-0.1C steel by repetitive heat treatment and recrystallization

Abstract: Abstract. Grain refinement in metals is well-known as one of the most effective methods to enhance their strength without addition of other elements. In this study, repetitive heat treatment combined with subsequent cold-rolling and recrystallization were investigated to obtain ultrafine-grained ferrite. Ultrafine-grained (UFG) ferritic structure having a mean grain size smaller than 1 m was fabricated by repetitive heat treatment at 810 °C for 180 s and cold rolling by 90 % plus a recrystallization heat trea… Show more

“…While thermomechanical treatment can refine the grain size of polycrystalline alloys and thus improve strength (23), we rule out grain size strengthening in the latter by compressing samples at 400°C to generate equiaxed grains of average size ~100 m and ~10 m, which generated the same hardness (see fig. S4).…”

Ultrahigh specific strength in a magnesium alloy strengthened by spinodal decomposition

“…While thermomechanical treatment can refine the grain size of polycrystalline alloys and thus improve strength (23), we rule out grain size strengthening in the latter by compressing samples at 400°C to generate equiaxed grains of average size ~100 m and ~10 m, which generated the same hardness (see fig. S4).…”

Ultrahigh specific strength in a magnesium alloy strengthened by spinodal decomposition

Effective grain size refinement of an Fe-24Ni-0.3C metastable austenitic steel by a modified two-step cold rolling and annealing process utilizing the deformation-induced martensitic transformation and its reverse transformation

Quantitative characterization of local deformation-fracture behavior in ferrite-martensite dual-phase steels with different martensite distributions