The co-addition of chromium (Cr) and tin (Sn) is known to enhance the wettability between copper (Cu) and graphite (Cgr), but the effect of Sn content remains poorly understood. This study aims to systematically investigate the influence of Sn content a (a = 0, 10, 20, 30, 40, 50, 80, 99 at. %) on the wettability, interfacial structure, surface/interface energy (σlv/σsl), and adhesion behavior of the Cu-aSn-1Cr/Cgr system at 1100 °C. The experimental results show that as the Sn content increases, the equilibrium contact angle (θe) of the metal droplet shows a non-monotonic trend; the thickness of the reaction product layer (RPL, consisting of Cr carbides (CrmCn)) gradually increases, accompanied by a decrease in the calculated adhesion work (Wadcal). A "sandwich" interface structure is observed, consisting of two interfaces: metal||CrmCn and CrmCn||Cgr. Sn content mainly affects the former. At metal||CrmCn, Sn exists in various forms (e.g., Cu-Sn solid solution, CuxSny compounds) in contact with CrmCn. To elucidate the wetting and bonding mechanisms of metal||CrmCn, simplified interfacial models are constructed and analyzed based on first-principles calculations of density functional theory (DFT). The trend of theoretically calculated results (σmetal and Wad) agrees with the experimental results (σlv and Wadcal). Further analysis of the partial density of state (PDOS) and charge density difference (CDD) reveals that charge distribution and bonding characteristics vary with Sn content, providing the microscopic insight into the nature of wettability and interfacial bonding strength.
Keywords: DFT; adhesion work; interface energy; stability; surface energy; wettability.