Tribological improvement of magnesium alloy using solid lubricant with cerium oxide catalysis under heating treatment conditions

This study aims to improve the tribological performance of magnesium alloy materials, a novel regulation method was proposed and investigated in this study.

First, magnesium alloy specimens were heat-treated in a muffle furnace with molybdenum disulfide powder as the medium and cerium oxide as the catalyst. Surface morphology, elemental composition and tribological performance were characterized via white light interferometry, X-ray diffractometry and, a reciprocating friction–wear tester.

The results reveal that surface roughness of the original sample and pure MoS₂ group deteriorates with rising temperature, mainly due to thermal volume expansion. In comparison, the CeO₂-catalyzed MoS₂ group possesses the lowest surface roughness and outstanding thermal deformation resistance. Meanwhile, CeO₂ catalysis induces the in situ formation of MgMoO₄ on the alloy surface. Benefiting from Mo element infiltration, this group achieves excellent tribological performance in physiological corrosion solution, especially after heat treatment at 300°C.

This study provides an innovative process method for tribological performance improving of magnesium alloy materials in physiological corrosion solution.