Title :
Pull-In and Release Voltage Design for Nanoelectromechanical Field-Effect Transistors
Author :
Kam, Hei ; Liu, Tsu-Jae King
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., Univ. of California, Berkeley, CA, USA
Abstract :
The Euler-Bernoulli beam equation is solved simultaneously with the Poisson equation in order to accurately model the switching behavior of nanoelectromechanical field-effect transistors (NEMFETs). Using this approach, the shape of the movable gate electrode and semiconductor potential across the width of the channel are derived for the various regimes of transistor operation (before gate pull-in, after gate pull-in, and at the point of gate release). The impact of various transistor design parameters such as the body doping concentration, gate work function, gate stiffness, and as-fabricated actuation gap thickness, as well as source-to-body bias voltage and surface forces, on the gate pull-in and gate release voltages are examined. A unified pull-in/release voltage model is developed to facilitate NEMFET design for digital- and analog-circuit applications.
Keywords :
Poisson equation; field effect transistors; micromechanical devices; nanoelectromechanical devices; Euler-Bernoulli beam equation; MEMS; NEMFET; Poisson equation; analog-circuit application; body doping concentration; digital-circuit applications; fabricated actuation gap thickness; gate electrode; gate stiffness; gate work function; nanoelectromechanical field-effect transistors; pull-in voltage design; release voltage design; source-to-body bias voltage; switching behavior; unified pull-in-release voltage model; Application software; CMOS technology; Electrodes; FETs; MOSFETs; Poisson equations; Semiconductor device doping; Shape; Switches; Threshold voltage; MEMS; Mechanical switch; nanoelectromechanical field-effect transistor (NEMFET); subthreshold swing; suspended-gate FET;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2009.2032617
