Title :
Ion-Implanted TiN Metal Gate With Dual Band-Edge Work Function and Excellent Reliability for Advanced CMOS Device Applications
Author :
Qiuxia Xu ; Gaobo Xu ; Huajie Zhou ; Huilong Zhu ; Qingqing Liang ; Jinbiao Liu ; Junfeng Li ; Jinjuan Xiang ; Miao Xu ; Jian Zhong ; Weijia Xu ; Chao Zhao ; Dapeng Chen ; Tianchun Ye
Author_Institution :
Inst. of Microelectron., Beijing, China
Abstract :
This paper proposed, for the first time, that the dual band-edge effective work functions are achieved by employing a single metal gate (MG) and single high-k (HK) dielectric via ion implantation into a TiN MG for HP CMOS device applications under a gate-last process flow. The P/BF2 ion-implanted TiN/HfO2/ILSiO2 gate-stack does not degrade the gate leakage, reliability, and carrier mobility, and reduces the effective oxide thickness. The impact of P/BF2 ion implant energy, dose, and TiN gate thickness on the properties of implanted TiN/HfO2/ILSiO2 gate-stack is studied, and the corresponding possible mechanisms are discussed. This technique has been successfully applied to the replacement MG and HK/MG last process flow to fabricate HP CMOSFETs and CMOS 32 frequency dividers with a minimum gate length of 25 nm.
Keywords :
MOSFET; carrier mobility; frequency dividers; high-k dielectric thin films; ion implantation; reliability; titanium compounds; work function; HP CMOSFET; TiN; advanced CMOS device applications; carrier mobility; dual band-edge work function; frequency dividers; gate leakage; ion-implanted metal gate; reliability; single high-k dielectric; single metal gate; CMOS integrated circuits; CMOSFETs; Hafnium compounds; High K dielectric materials; Titanium; CMOSFETs; P/BF₂ ion-implanted TiN metal gate (MG); dual band-edge (DBE) effective work function (EWF); p/BF2 ion-implanted TiN metal gate (MG); single MG and single high- $k$ (HK); single MG and single high-k (HK).;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2015.2494080
