Title :
Scaling planar silicon devices
Author :
Chuang, Ching-Te ; Bernstein, Kerry ; Joshi, Rajiv V. ; Puri, Ruchir ; Kim, Keunwoo ; Nowak, Edward J. ; Ludwig, Thomas ; Aller, Ingo
Author_Institution :
IBM T. J. Watson Res. Center, Yorktown Heights, NY, USA
Abstract :
The generation-over-generation scaling of critical CMOS technology parameters is ultimately bound by nonscalable limitations, such as the thermal voltage and the elementary electronic charge. Sustained improvement in performance and density has required the introduction of new device structures and materials. Partially depleted SOI, a most recent MOSFET innovation, has extended VLSI performance while introducing unique idiosyncrasies. Fully depleted SOI is one logical extension of this device design direction. Gate dielectric tunneling, device self-heating, and single-event upsets present developers of these next-generation devices with new challenges. Strained silicon and high-permittivity gate dielectric are examples of new materials that will enable CMOS developers to continue to deliver device performance enhancements in the sub-100 nm regime.
Keywords :
CMOS integrated circuits; MOSFET; VLSI; dielectric thin films; elemental semiconductors; permittivity; silicon; silicon-on-insulator; tunnelling; 100 nm; MOSFET; Si; Si-SiO2; VLSI; critical CMOS technology parameter scaling; device self-heating; fully depleted SOI; gate dielectric tunneling; high-permittivity gate dielectrics; partially depleted SOI; planar silicon device scaling; single-event upsets; strained silicon; Circuit synthesis; Circuit topology; FinFETs; High K dielectric materials; MOSFET circuits; Semiconductor films; Silicon devices; Silicon germanium; Silicon on insulator technology; Voltage;
Journal_Title :
Circuits and Devices Magazine, IEEE
DOI :
10.1109/MCD.2004.1263403
