Abstract
Superplastic materials are capable of exhibiting large tensile elongation at elevated temperature, which is of great industrial significance because it forms the basis of a fabrication method to produce complex shapes. Superplasticity with elongation larger than 500% has been widely realized in many metals and alloys, but seldomly been succeeded in low carbon low alloy steel, even though it is commercially applied in the largest quantity. Here we report ultrahigh superplastic elongation of 900–1200% in the FeMnAl low carbon steels at high strain rate of 10−2–10−3 s−1. Such high-strain-rate superplasticity was attributed to dynamic austenite reverse phase transformation from a heavily cold rolled ferrite to fine-grained ferrite/austenite duplex microstructure and subsequent limited dynamic grain coarsening, under which a large fraction of high angle boundaries can be resulted for superplastic deformation. It is believed that this finding of the low carbon low alloy steel with ultrahigh superplasticity and relative low cost would remarkably promote the application of superplastic forming technique in automobile, aeronautical, astronautical and other fields.
Highlights
Superplasticity is referred to the ability of a material to sustain large plastic deformation (elongation-to-failure: ΔL/L0 > 100%) in tension
Superplasticity is referred to the ability of a material to sustain large plastic deformation in tension
The cast ingots of about 50 kg were produced by conventional melting and mold casting. These ingots were forged and hot rolled into sheets in thickness of about 6 mm and air cooled to room temperature (RT), thereafter softened at 650 °C and further RT coldly rolled to 1.8 mm in thickness
Summary
Superplasticity is referred to the ability of a material to sustain large plastic deformation (elongation-to-failure: ΔL/L0 > 100%) in tension. We demonstrate newly designed low carbon low alloy steels with excellent high-strain-rate superplasticity.
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