Title :
A planar transistor for the 32-nm node and beyond with an ultra-shallow junction fabricated using in-situ doped selective Si epitaxy
Author :
Kikuchi, Y. ; Tateshita, Y. ; Kataoka, T. ; Wang, J. ; Miyanami, Y. ; Kugimiya, K. ; Kimura, T. ; Ikuta, T. ; Ikeda, H. ; Fujita, S. ; Yamamoto, R. ; Kanda, S. ; Tagawa, Y. ; Iwamoto, H. ; Ohno, T. ; Kobayashi, T. ; Saito, M. ; Kadomura, S. ; Nagashima, N
Author_Institution :
Sony Corp., Atsugi
Abstract :
Shallower junctions must be formed to make transistors work for the 32-nm node. Many kinds of technologies, such as co-implantation, laser spike annealing (LSA), and flash lamp annealing, have been energetically studied to form ultra-shallow junctions. We focused on in-situ doped selective Si epitaxy, with which the short channel effect and the parasitic resistance can be made compatible. Using this epitaxy, ultra-shallow junctions (with effective junction depths (Xj,eff) under 9 nm@5E18) were formed, and 20-nm or shorter PMOS gate transistors were fabricated using the epitaxy
Keywords :
MOSFET; epitaxial layers; semiconductor doping; silicon; 20 nm; 32 nm; PMOS gate transistors; Si; doping; epitaxial layer; flash lamp annealing; laser spike annealing; parasitic resistance; planar transistor; short channel effect; ultra-shallow junction; Annealing; Epitaxial growth; Fabrication; Impurities; Ion implantation; MOSFETs; Parasitic capacitance; Semiconductor lasers; Shape; Silicon compounds;
Conference_Titel :
Solid-State Device Research Conference, 2006. ESSDERC 2006. Proceeding of the 36th European
Conference_Location :
Montreux
Print_ISBN :
1-4244-0301-4
DOI :
10.1109/ESSDER.2006.307643
