Enhanced strength-ductility of CoCrFeMnNi high-entropy alloy with inverse gradient-grained structure prepared by laser surface heat-treatment technique

The inverse gradient-grained CoCrFeMnNi high-entropy alloy with a desirable mechanical property that evades the strength-ductility trade-off is fabricated by the process of cold rolling and subsequent laser surface heat-treatment. Due to the gradually decayed thermal effect along with the thickness, the grain size increases from the hard core to the soft surface in terms of the inverse gradient-grained sample, which is in good consistent with the microhardness profiles. The hetero-deformation induced strengthen-ing and strain hardening caused by the inverse gradient-grained structure improve the strength-ductility combination, as well as the high-order hierarchal nanotwins due to the enhanced interaction with dis-locations. For the laser surface heat-treatment technique, the strength and ductility are significantly in-creased by enlarging the microhardness difference and decreasing the thermal stress. Considering the high volume fraction of gradient-grained layer and a great deal of high-order hierarchal nanotwins in the central region, the laser surface heat-treatment technique is a promising way to produce the gradient-structured materials without thickness limitation. (c) 2021 Published by Elsevier Ltd on behalf of Chinese Society for Metals.

Automated summary

The inverse gradient-grained CoCrFeMnNi high-entropy alloy with desirable mechanical properties is fabricated using cold rolling and subsequent laser surface heat-treatment. This material exhibits a unique grain structure and improved strength-ductility combination. The laser surface heat-treatment technique further enhances the strength and ductility by controlling microhardness and thermal stress. This technique shows promise for producing gradient-structured materials without thickness limitation.