Wettability between Titanium‐Containing Steels and TiC Ceramic Substrate

Abstract: TiC particles, known for their extremely high hardness, are commonly used in metal‐matrix composite to enhance wear resistant. Precipitating TiC particles during the solidification stage of steel proves to be an effective method for improving product properties. Herein, TiC particles are determined to precipitate during the solidification process of titanium‐containing steels (Ti>0.3 wt%) through in situ observation experiment and energy spectrum analysis. To investigate the crucial factor of wettability, w… Show more

“…Capillary forces drive the liquid phase to fill the gaps between particles, promoting particle aggregation, increasing the contact area between particles, enhancing mass transfer, and facilitating easier diffusion of atoms between adjacent titanium particles through the liquid-phase channels. Compared to molten MgCl 2 , molten Mg exhibits better wetting properties toward titanium and stronger capillary action [ 36 ], which promotes particle aggregation and leads to larger aggregate sizes. Additionally, molten Mg reduces the oxide layer on the surface of titanium particles, accelerating mass transfer between particles and promoting particle aggregation.…”

Aggregation–Growth and Densification Behavior of Titanium Particles in Molten Mg-MgCl2 System

“…Capillary forces drive the liquid phase to fill the gaps between particles, promoting particle aggregation, increasing the contact area between particles, enhancing mass transfer, and facilitating easier diffusion of atoms between adjacent titanium particles through the liquid-phase channels. Compared to molten MgCl 2 , molten Mg exhibits better wetting properties toward titanium and stronger capillary action [ 36 ], which promotes particle aggregation and leads to larger aggregate sizes. Additionally, molten Mg reduces the oxide layer on the surface of titanium particles, accelerating mass transfer between particles and promoting particle aggregation.…”

Aggregation–Growth and Densification Behavior of Titanium Particles in Molten Mg-MgCl2 System