Title :
Nickel-Silicided Schottky Junction CMOS Transistors With Gate-All-Around Nanowire Channels
Author :
Tan, E.J. ; Pey, K.L. ; Singh, N. ; Lo, G.Q. ; Chi, D.Z. ; Chin, Y.K. ; Tang, L.J. ; Lee, P.S. ; Ho, C.K.F.
Author_Institution :
Inst. of Microelectron., Singapore
Abstract :
We demonstrate high-performance Schottky CMOS transistors with NiSi source/drain and gate-all-around (GAA) silicon nanowire (~5 nm) channels. The transistors exhibit good I on/I off characteristics, along with fully controlled shortchannel effects revealed by low drain-induced barrier lowering (~10 mV/V) and near-ideal subthreshold swing (~60 mV/dec). Although the N-MOSFET required dopant segregation to suppress the ambipolar behavior, excellent P-MOSFET characteristics could be achieved without the use of barrier modification techniques. We attribute this to the Schottky barrier thinning in a nanosized metal-semiconductor junction and superior gate electrostatic control in a GAA nanowire architecture.
Keywords :
CMOS integrated circuits; MOSFET; Schottky barriers; Schottky gate field effect transistors; nanowires; nickel compounds; p-n junctions; Ion/Ioff characteristics; N-MOSFET; P-MOSFET characteristics; Schottky CMOS transistors; Schottky barrier thinning; barrier modification techniques; dopant segregation; drain-induced barrier lowering; gate electrostatic control; gate-all-around nanowire channels; gate-all-around silicon nanowire channels; nanosized metal-semiconductor junction; near-ideal subthreshold swing; nickel-silicided Schottky junction CMOS transistors; shortchannel effects; source/drain; Conductivity; Doping profiles; Electrostatics; Helium; MOSFET circuits; Materials science and technology; Microelectronics; Schottky barriers; Silicon; Student members; Gate-all-around (GAA) MOSFET; Schottky source/drain; silicon nanowire (SiNW);
Journal_Title :
Electron Device Letters, IEEE
DOI :
10.1109/LED.2008.2000876
