Title :
Gate-Stack Engineering in n-Type Ultrascaled Si Nanowire Field-Effect Transistors
Author :
Luisier, Mathieu ; Schenk, Olaf
Author_Institution :
Integrated Syst. Lab., ETH Zurich, Zurich, Switzerland
Abstract :
The electrical properties of gate-stacks composed of an interfacial SiOx layer and different types of high-κ dielectrics are theoretically investigated for potential applications as oxide layers in ultrascaled Si nanowire field-effect transistors with a gate length of 5 nm. As a simulation tool, a 3-D quantum transport solver based on the effective mass approximation and including gate leakage currents is employed. We determine how the dielectric constant of the high-κ layer and its conduction band offset with Si must be engineered so that an equivalent oxide thickness of 0.5-0.6 nm can be achieved while maintaining the transistor OFF-state current <;0.1 μA/μm.
Keywords :
field effect transistors; high-k dielectric thin films; leakage currents; nanowires; permittivity; silicon compounds; 3D quantum transport solver; Si; SiO; conduction band offset; dielectric constant; effective mass approximation; gate leakage currents; gate stacks; gate-stack engineering; high-κ dielectrics; interfacial layer; size 0.5 nm to 0.6 nm; size 5 nm; ultrascaled nanowire field-effect transistors; Dielectrics; Effective mass; Field effect transistors; Leakage currents; Logic gates; Silicon; Device scaling; gate leakage; quantum transport simulation;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2013.2278573
