Title :
Self-forces in 3D finite element Monte Carlo simulations of a 10.7 nm gate length SOI FinFET
Author :
Aldegunde, Manuel ; Kalna, Karol
Author_Institution :
Electron. Syst. Design Centre, Swansea Univ., Swansea, UK
Abstract :
Particle-mesh coupling in ensemble Monte Carlo simulations of semiconductor devices results in unphysical self-forces when using unstructured meshes to describe the device geometry. We develop a correction to the driving electric field and show that self-forces can be virtually eliminated on a finite element mesh at a small additional computational cost. The developed methodology is included into a self-consistent 3D finite element Monte Carlo device simulator. We simulate an isolated particle and show the kinetic energy conservation down to a magnitude of 10-10 meV. The methodology is applied to a 10.7 nm gate length FinFET simulation and we find that for a large enough ensemble of particles, the impact of self-forces on the final ID-VG is almost negligible.
Keywords :
MOSFET; Monte Carlo methods; electric fields; finite element analysis; silicon-on-insulator; SOI FinFET; computational cost; device geometry; electric field; isolated particle; kinetic energy conservation; particle-mesh coupling; self-consistent 3D finite element Monte Carlo device simulator; size 10.7 nm; unphysical self-forces; unstructured meshes; Electric potential; FinFETs; Kinetic energy; Logic gates; Monte Carlo methods; Scattering;
Conference_Titel :
Simulation of Semiconductor Processes and Devices (SISPAD), 2014 International Conference on
Conference_Location :
Yokohama
Print_ISBN :
978-1-4799-5287-8
DOI :
10.1109/SISPAD.2014.6931594
