Author :
Ando, T. ; Hirano, T. ; Tai, K. ; Yamaguchi, S. ; Kato, T. ; Hagimoto, Y. ; Watanabe, K. ; Yamamoto, R. ; Kanda, S. ; Nagano, K. ; Terauchi, S. ; Tateshita, Y. ; Tagawa, Y. ; Saito, M. ; Iwamoto, H. ; Yoshida, S. ; Watanabe, H. ; Nagashima, N. ; Kadomura,
Abstract :
Sub-1nm EOT and high electron mobility were realized at the same time with HfSix/HfO2 gate stacks. It was revealed that there exist two mobility degradation modes depending on the HfO2 thickness and the HfSix composition. One is the crystallization in the thick HfO2 case (Tinv > 1.6 nm). The other is the Hf penetration into the interfacial layer with the Si substrate (bottom-IFL) in the thin HfO2 case (Tinv < 1.6 nm) for the Hf-rich electrode. We have demonstrated that carefully optimizing the HfO2 thickness and introducing a novel "Si extrusion" process from the HfSix electrode can suppress both modes. As a result, a high electron mobility equivalent to n+poly-Si/SiO2 (248 cm2/Vs @ Eeff = 1 MV/cm) was obtained at the sub-1nm EOT region for the very first time. The successful scaling together with a well-controlled Vth roll-off led to an extremely high Ion of 1165 muA/mum (@ Ioff = 81 nA/mu) at Vdd = 1.0V for a 45nm gate nMOSFET
Keywords :
MOSFET; crystallisation; electron mobility; extrusion; hafnium compounds; nanotechnology; silicon; 1 V; 1 nm; 45 nm; EOT; Hf penetration; Si substrate; Si-HfSi-HfO2; crystallization; extrusion process; gate nMOSFET; gate stack; gate stacks; high electron mobility; interfacial layer; mobility degradation modes; Annealing; CMOS technology; Degradation; Electrodes; Electron mobility; Hafnium oxide; High K dielectric materials; High-K gate dielectrics; Hysteresis; MOSFET circuits;
