Title :
Monte Carlo Simulations of High-Performance Implant Free In0.3Ga 0.7As Nano-MOSFETs for Low-Power CMOS Applications
Author :
Kalna, Karol ; Wilson, James A. ; Moran, David A J ; Hill, Richard J W ; Long, Andrew R. ; Droopad, Ravi ; Passlack, Matthias ; Thayne, Iain G. ; Asenov, Asen
Author_Institution :
Nanoelectron. Res. Centre, Glasgow Univ.
Abstract :
The potential performance of implant free heterostructure In0.3Ga0.7As channel MOSFETs with gate lengths of 30, 20, and 15 nm is investigated using state-of-the-art Monte Carlo (MC) device simulations. The simulations are carefully calibrated against the electron mobility and sheet density measured on fabricated III-V MOSFET structures with a high-kappa dielectric. The MC simulations show that the 30 nm gate length implant free MOSFET can deliver a drive current of 2174 muA/mum at 0.7 V supply voltage. The drive current increases to 2542 muA/mum in the 20 nm gate length device, saturating at 2535 muA/mum in the 15 nm gate length one. When quantum confinement corrections are included into MC simulations, they have a negligible effect on the drive current in the 30 and 20 nm gate length transistors but lower the 15 nm gate length device drive current at 0.7 V supply voltage by 10%. When compared to equivalent Si based MOSFETs, the implant free heterostructure MOSFETs can deliver a very high performance at low supply voltage, making them suitable for low-power high-performance CMOS applications
Keywords :
CMOS integrated circuits; III-V semiconductors; MOSFET; Monte Carlo methods; electron mobility; gallium arsenide; indium compounds; nanoelectronics; semiconductor device models; semiconductor heterojunctions; 0.7 V; 15 nm; 20 nm; 30 nm; III-V MOSFET structures; In0.3Ga0.7As; Monte Carlo device simulations; Si based MOSFET; drive current; electron mobility; gate length device; gate length device drive current; gate length transistors; high-K dielectric; high-performance implant free semiconductor channel nanoMOSFET; implant free heterostructure; low-power CMOS applications; potential performance; quantum confinement corrections; sheet density; supply voltage; Density measurement; Dielectric measurements; Electron mobility; III-V semiconductor materials; Implants; MOSFETs; Monte Carlo methods; Nanoscale devices; Potential well; Voltage; InGaAs nano-MOSFETs; Monte Carlo simulation; high performance; implant free;
Journal_Title :
Nanotechnology, IEEE Transactions on
DOI :
10.1109/TNANO.2006.888543
