Ferrite phase transformation in dual-phase steel under shock loading

Microstructural changes and ferrite phase transformation under shock loading, between 8.5 GPa and 17.5 GPa, in a hot-rolled Lean Duplex Stainless Steel (commercially known as LDX 2101) were investigated in as-received and pre-deformed conditions. The latter condition was considered to distinguish classical deformation twins at high strain rates from those associated to the reversible ferrite phase transformation. Plate impact experiments were used to introduce compressive shock loading at peak stresses below and above the stress threshold of the ferrite phase transformation, 13 GPa. Effects of shock loading were also examined by compressing shocked samples quasi-statically and comparing their response with those tested in the as-received condition. The microstructural examinations revealed that the ferrite in LDX 2101 experienced a reversible phase transformation at a peak stress of similar to 17 GPa. The fingerprints for this transformation were {112} < 111 > primary twins and {332}< 113 > primary and secondary twins. In addition, the yield stress of the sample pre-shocked at similar to 17 GPa showed a considerable increase (similar to 150 MPa) compared to the flow stress in as-received conditions.

Automated summary

Microstructural changes and ferrite phase transformation under shock loading between 8.5 GPa and 17.5 GPa in a hot-rolled Lean Duplex Stainless Steel were investigated, revealing a reversible phase transformation in ferrite at a peak stress of around 17 GPa, leading to a considerable increase in yield stress.