Electrical characterization and material evaluation of zirconium oxynitride gate dielectric in TaN-gated NMOSFETs with high-temperature forming gas annealing

Abstract

The electrical, material, and reliability characteristics of zirconium oxynitride (Zr-oxynitride) gate dielectrics were evaluated. The nitrogen (/spl sim/1.7%) in Zr-oxynitride was primarily located at the Zr-oxynitride/Si interface and helped to preserve the composition of the nitrogen-doped Zr-silicate interfacial layer (IL) during annealing as compared to the ZrO/sub 2/ IL - resulting in improved thermal stability of the Zr-oxynitride. In addition, the Zr-oxynitride demonstrated a higher crystallization temperature (/spl sim/600/spl deg/C) as compared to ZrO/sub 2/ (/spl sim/400/spl deg/C). Reliability characterization was performed after TaN-gated nMOSFET fabrication of Zr-oxynitride and ZrO/sub 2/ devices with equivalent oxide thickness (EOTs) of 10.3 /spl Aring/ and 13.8 /spl Aring/, respectively. Time-zero dielectric breakdown and time-dependent dielectric breakdown (TDDB) characteristics revealed higher dielectric strength and effective breakdown field for the Zr-oxynitride. High-temperature forming gas (HTFG) annealing on TaN/Zr-oxynitride nMOSFETs with an EOT of 11.6 /spl Aring/ demonstrated reduced D/sub it/, which resulted in reduced swing (69 mV/decade), reduced off-state leakage current, higher transconductance, and higher mobility. The peak mobility was increased by almost fourfold from 97 cm/sup 2//V/spl middot/s to 383 cm/sup 2//V/spl middot/s after 600/spl deg/C HTFG annealing.