Deformation behavior and spall fracture of the Hadfield steel under shock-wave loading

Abstract: Comparative studies of regularities in plastic deformation and fracture of the Hadfield polycrystalline steel upon quasi-static tension, impact failure, and shock-wave loading with rear spall are performed. The SINUS-7 accelerator was used as a shock-wave generator. The electron beam parameters of the accelerator were the following: maximum electron energy was 1.35 MeV, pulse duration at half-maximum was 45 ns, maximum energy density on a target was 3.4⋅10 10 W/cm 2 , shock-wave amplitude was ~20 GPa, and stra… Show more

“…For example, the cooling rates have been calculated [9,[25][26][27]and investigated experimentally [28] to be of the order of 10 8 -10 9 K/s. Such a drastic temperature variation induces the formation of thermal stresses and shock waves reaching several hundreds of Mpa, which would induce severe surface deformation the materials [29][30][31][32][33].With repeated heating and cooling induced by successive pulsed electron beams irradiation, it has been observed that precipitates are partially or completely dissolved and that chemistry segregations are drastically reduced in the top surface melted layer where supersaturated solid solution can form [34,35].These microstructural changes improve the corrosion resistances of the surface layer which has been established in various alloys such as steels [34][35][36][37], Mg alloys [38][39][40]and Al alloys [41].Besides, due to the effect of dynamic stress fields induced by the drastic thermal processes on the material, plastic deformation occurs at the treated surface and subsurface layers, resulting in surface and subsurface microhardness enhancement [30,37,42].…”

Surface modifications of a cold rolled 2024 Al alloy by high current pulsed electron beams

“…For example, the cooling rates have been calculated [9,[25][26][27]and investigated experimentally [28] to be of the order of 10 8 -10 9 K/s. Such a drastic temperature variation induces the formation of thermal stresses and shock waves reaching several hundreds of Mpa, which would induce severe surface deformation the materials [29][30][31][32][33].With repeated heating and cooling induced by successive pulsed electron beams irradiation, it has been observed that precipitates are partially or completely dissolved and that chemistry segregations are drastically reduced in the top surface melted layer where supersaturated solid solution can form [34,35].These microstructural changes improve the corrosion resistances of the surface layer which has been established in various alloys such as steels [34][35][36][37], Mg alloys [38][39][40]and Al alloys [41].Besides, due to the effect of dynamic stress fields induced by the drastic thermal processes on the material, plastic deformation occurs at the treated surface and subsurface layers, resulting in surface and subsurface microhardness enhancement [30,37,42].…”

Surface modifications of a cold rolled 2024 Al alloy by high current pulsed electron beams

Simulation and experimental investigation of the spall fracture of 304L stainless steel irradiated by a nanosecond relativistic high-current electron beam

Comparative study of shock-wave hardening and substructure evolution of 304L and Hadfield steels irradiated with a nanosecond relativistic high-current electron beam