Semiconductor device fabricated by reducing carbon, sulphur, and oxygen impurities in a calcium-doped copper surface

Abstract

A semiconductor device having contaminant-reduced calcium-copper (Ca—Cu) alloy surfaces formed on Cu interconnects fabricated by cost-effectively removing the contaminant layer. Contaminant removal from a Cu—Ca—X surface, where contaminant X═C, S, or O, is achieved by sputtering the Cu—Ca—X surface in an argon (Ar) atmosphere between the steps of (a) immersing the Cu interconnect surface into an electroless plating solution comprising Cu salts, Ca salts, their complexing agents, a reducing agent, a pH adjuster, and at least one surfactant for facilitating Ca-doping of the Cu interconnect material; and (b) annealing of the Ca—Cu alloy surface onto the underlying Cu interconnect material to form a Ca—Cu/Cu interconnect structure, whereby the sputtering step, under Ar, selectively and effectively removes contaminants from the Cu—Ca—X layer containing higher concentrations of C, S, or O, thereby minimizing the post-annealed contaminant level, and thereby producing a uniform Ca—Cu alloy surface (i.e., Cu-rich with 0.2-5% Ca) on the Cu interconnect material for maximizing Ca—Cu/Cu interconnect structure reliability, electromigration resistance, and corrosion prevention. The annealing step primarily removes O and secondarily removes C and S, especially when performed under vacuum, an inert gas, or a reducing ambient such as ammonia (NH ) plasma. Thus, the resultant device then comprises a distinctive contaminant-reduced Ca—Cu/Cu interconnect structure.