Role of MoS₂ Addition in the Consolidation of Metal from Powder to Plate by the Compression Shearing Method at Room Temperature

摘要

We use a Cu/MoS_(2) composite to provide a new approach to control the consolidation of materials by compression–shearing at room temperature. Cu/MoS_(2) samples were formed under several shearing distances and the resulting microstructures were observed and compared with pure Cu samples. The microstructural change related to the decrease in applied shearing force is discussed. The structural observations indicate that the reason for the decrease in shearing force appears to be the slip of the sample on the lower plate because of MoS_(2) lubrication. The internal structure of the Cu/MoS_(2) samples appears to be interrupted midway through the consolidation process by dissipating the applied shearing force. In contrast, particle bonding and grain refinement occurred only on the sample surface, as for the friction process, and extended gradually to the inside of the sample when the shearing distance increased. We controlled the metal consolidation by compression shearing at room temperature by dispersing MoS_(2) into a Cu matrix. The shearing force appears to be more effective in metal consolidation by compression shearing at room temperature than the shearing distance.