Title :
Study of High-Performance Ge pMOSFET Scaling Accounting for Direct Source-to-Drain Tunneling
Author :
Ho, Byron ; Xu, Nuo ; Liu, Tsu-Jae King
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., Univ. of California at Berkeley, Berkeley, CA, USA
Abstract :
Drift-diffusion models are used in conjunction with Monte Carlo simulations to study and compare the scalability of germanium (Ge) versus silicon (Si) p-channel double-gate MOSFETs near the end of the technology roadmap. Direct source-to-drain tunneling (DSDT) and uniaxial compressive stress effects are taken into account. The higher dielectric constant of Ge results in degraded short-channel effects and lower drive currents for a given off-state leakage specification. With large compressive uniaxial channel stress (1.5 GPa), Ge can outperform Si for gate lengths (Lg) greater than 15 nm. Due to its lower effective hole transport mass, Ge suffers more from DSDT, resulting in degraded p-channel MOSFET performance at very short Lg.
Keywords :
MOSFET; Monte Carlo methods; compressive strength; elemental semiconductors; germanium; hole traps; leakage currents; permittivity; silicon; tunnelling; DSDT; Ge; Monte Carlo simulations; Si; compressive uniaxial channel stress; degraded p-channel MOSFET performance; degraded short-channel effects; dielectric constant; direct source-to-drain tunneling; drift-diffusion models; drive currents; gate lengths; germanium p-channel double-gate MOSFET; high-performance pMOSFET scaling accounting; hole transport mass; off-state leakage specification; silicon p-channel double-gate MOSFET; technology roadmap; uniaxial compressive stress effects; Compressive stress; Effective mass; Logic gates; MOSFET circuits; Performance evaluation; Silicon; Tunneling; Double-gate (DG) FETs; MOSFET; germanium; source–drain tunneling;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2011.2159008
