Separating the reaction and spark plasma sintering effects during the formation of TiC–Cu composites from mechanically milled Ti–C–3Cu mixtures

Abstract

Abstract The goal of this work was to separate the reaction and spark plasma sintering (SPS) effects during the in-situ synthesis of TiC in mechanically milled Ti–C–3Cu powder mixtures. The powders were milled for 3–10\xa0min in a high-energy planetary ball mill. Structural changes occurring in the reaction mixtures during thermal explosion (TE) in a furnace and SPS in a graphite die were compared. Although the maximum temperature of TE reached the melting point of copper in some samples, no evidence of extensive melting was observed in the microstructure of the products of TE. The ignition and maximum temperatures of TE were found to decrease with increasing milling time of the mixture. In the mixture milled for 10\xa0min, the maximum temperature of TE was only 820\xa0°C. Melting of copper at the inter-particle contacts during SPS was observed in samples milled for 5–10\xa0min (SPS at 900–980\xa0°C) and caused the formation of TiC-depleted regions in the microstructure. Those regions were the re-solidified melt partially filling the pores between the agglomerates. Based on the analysis of the TE parameters in the mixtures and microstructures of the products of TE and SPS, melting during SPS was attributed to the effect of electric current (a high electric current density at the inter-particle contacts) and not to the heat of reaction. The hardness, compressive strength and Young s modulus of the sintered composites are reported. A TiC–Cu composite (milling time 5\xa0min, SPS at 980\xa0°C, relative density 93%) shows a compressive yield strength of 890\xa0MPa and an ultimate compressive strength of 920\xa0MPa.