Title :
Low-power DRAM-compatible Replacement Gate High-k/Metal Gate stacks
Author :
Ritzenthaler, R. ; Schram, T. ; Bury, E. ; Mitard, J. ; Ragnarsson, L. Å ; Groeseneken, G. ; Horiguchi, N. ; Thean, A. ; Spessot, A. ; Caillat, C. ; Srividya, V. ; Fazan, P.
Author_Institution :
imec, Leuven, Belgium
Abstract :
In this paper, the feasibility of High-k/Metal Gate (HKMG) Replacement Metal Gate (RMG) stacks for low power DRAM compatible transistors is assessed. It is shown that traditional RMG gate stacks cannot be used because of the additional anneal needed in a DRAM process. New solutions are developed, and a PMOS stack HfO2/TiN with TiN deposited in three times combined with Work Function metal oxidations is demonstrated, featuring a Work Function of 4.95 eV. On the NMOS side, a new solution based on the use of oxidized Ta as a diffusion barrier is proposed, and a HfO2/TiN/Ta/TiAl/TiN/TiN gate stack featuring an aggressive Work Function of 4.35 eV (allowing a Work Function separation of 600 mV between NMOS and PMOS) is demonstrated.
Keywords :
DRAM chips; MOS memory circuits; low-power electronics; DRAM compatible transistor; DRAM-compatible replacement gate; HfO2; NMOS; PMOS; Ta; TiAl; TiN; high-k-metal gate replacement metal gate stack; high-k-metal gate stacks; voltage 600 mV; work function metal oxidation; Annealing; Hafnium compounds; Logic gates; MOS devices; Random access memory; Tin; DRAM; RMG (Replacement Metal Gate); Work Function Engineering; periphery transistors;
Conference_Titel :
Solid-State Device Research Conference (ESSDERC), 2012 Proceedings of the European
Conference_Location :
Bordeaux
Print_ISBN :
978-1-4673-1707-8
Electronic_ISBN :
1930-8876
DOI :
10.1109/ESSDERC.2012.6343378
