Microstructure and properties of laser-melted FeCoCrNiSiMox high-entropy alloy coatings

Abstract

Abstract In this research, FeCoCrNiSiMox high-entropy alloy coatings were created using laser cladding technology on 45 steel surfaces in order to provide a coating with high hardness and strong abrasion resistance. The present study aims to evaluate the effects of including Mo elements on the tissue, structure, and mechanical characteristics of FeCoCrNiSiMox high mercury alloy coatings under optimal laser melting process conditions. Through the regulation of Mo element incorporation, it has been observed that for values of x less than or equal to 0.2, the coating exhibits a singular FCC structure. However, for values of x greater than 0.2, a phase transition occurs in the coating’s structure, resulting in the appearance of a second phase. Consequently, the alloy primarily comprises a solid solution phase combined with the FCC phase and the Mo-rich phase. The introduction of the Mo element results in a steady reduction in the microstructure of the coating, which predominantly consists of dendritic structures. Additionally, the average hardness of the coating exhibits an increase, accompanied by an enhancement in its wear resistance.