Title :
Uniform, Low-Resistive Ni-Pt Silicide Fabricated by Partial Conversion With Low Metal-Consumption Ratio
Author :
Futase, Takuya ; Kamino, Takeshi ; Inaba, Yutaka ; Tanimoto, Hisanori
Author_Institution :
Grad. Sch. of Pure & Appl. Sci., Univ. of Tsukuba, Tsukuba, Japan
Abstract :
We applied partial conversion (PC) with a low metal-consumption ratio (MCR) as the initial silicidation, fabricating uniform and low-resistive Ni-Pt silicide regardless of the device patterns across a wafer. The key to PC in Ni-Pt silicidation was leaving the Ni-Pt alloy on the silicide after the initial silicidation. This process enriched the Pt of the Ni-Pt silicide because the Pt was supplied from the unconsumed Ni-Pt alloy on the silicide during the initial silicidation. The resistivity of Ni-Pt silicide was as low as that of NiSi at MCRs of less than 80%, suppressing the formation of nickel di-silicide (NiSi2) on the even narrow active line. We concluded that Pt on the silicide/Si interface and the grain boundaries of silicides can restrain Ni diffusion toward the <;110>; direction into the Si substrate, which suppresses the formation of NiSi2.
Keywords :
grain boundaries; nanofabrication; nickel alloys; platinum alloys; Ni-Pt alloy; Ni-PtSi; Si substrate; device patterns; grain boundaries; low metal-consumption ratio; nickel di-silicide; partial conversion; restrain Ni diffusion; silicidation; silicide/Si interface; uniform low-resistive Ni-Pt silicide; wafer; Conductivity; Diffusion processes; Nickel alloys; Rapid thermal annealing; Silicidation; Silicides; Diffusion; Ni-Pt; metal-consumption ratio (MCR); partial conversion (PC); rapid thermal annealing (RTA); resistivity; silicide;
Journal_Title :
Semiconductor Manufacturing, IEEE Transactions on
DOI :
10.1109/TSM.2011.2163951
