Novel and cost-efficient single metallic silicide integration solution with dual Schottky-barrier achieved by aluminum inter-diffusion for FinFET CMOS technology with enhanced performance

Novel and cost-efficient single metallic silicide integration solution with dual Schottky-barrier achieved by aluminum inter-diffusion for FinFET CMOS technology with enhanced performance

We have developed a novel and cost-efficient silicide integration solution to achieve a hole barrier height of 215 meV and electron barrier height of 665 meV simultaneously with a single metallic silicide based on aluminum inter-diffusion. It is proposed that aluminum diffuses into PtSi and forms an...

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Hauptverfasser: Lee, R.T-P., Koh, A.T-Y., Wei-Wei Fang, Kian-Ming Tan, Lim, A.E-J., Tsung-Yang Liow, Chow Shue-Yin, Yong, A.M., Hoong Shing Wong, Guo-Qiang Lo, Samudra, G.S., Dong-Zhi Chi, Yee-Chia Yeo
Format: Tagungsbericht
Sprache:eng
Schlagworte:
Annealing
FinFETs
Performance evaluation
Resistance
Silicides
Silicon
Silicon germanium
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Beschreibung
Zusammenfassung:We have developed a novel and cost-efficient silicide integration solution to achieve a hole barrier height of 215 meV and electron barrier height of 665 meV simultaneously with a single metallic silicide based on aluminum inter-diffusion. It is proposed that aluminum diffuses into PtSi and forms an alloy, which lowers the electron barrier height of PtSi due to a change in the intrinsic PtSi workfunction. Additionally, we have integrated platinum germanosilicide with an ultra-low hole barrier height of 215 meV in P-FinFETs to provide a 21% enhancement in drive current performance, which is attributed to the 20% reduction in series resistance. We have also ascertained the compatibility of PtSiGe with laser thermal annealing for further performance enhancement.
ISSN:0743-1562
DOI:10.1109/VLSIT.2008.4588551