Title :
Threshold voltage model for double gate p-IMOS
Author :
Heming Yao ; Foad, Saddam
Author_Institution :
Beihang Sino-French Eng. Sch., Beihang Univ., Beijing, China
Abstract :
IMOS device with the low static power consumption and the sub threshold swing is obviously superior to the traditional CMOS device. However, the single gate IMOS (SG IMOS) requires a relatively high gate voltage to cause the avalanche breakdown, and the partition structure of its channel leads to a reduction of the integration degree. This paper presents a double gate p-IMOS (DG p-IMOS). By solving the two-dimensional Possion equations and using the different regions of different electric field distribution and the avalanche breakdown condition, DG p-IMOS threshold voltage equation is obtained. By analyzing the model, the dependences of threshold voltage on drain-source voltage, Si layer thickness and gate length are studied. The model is compared with the SG p-IMOS to verify the advantages of DG p-IMOS. The results of the model are in good agreement with the 2D simulation results.
Keywords :
MOSFET; Poisson equation; avalanche breakdown; electric fields; elemental semiconductors; low-power electronics; semiconductor device models; silicon; DG p-IMOS threshold voltage equation; avalanche breakdown eondition; channel partition structure; double gate p-IMOS; drain-source voltage; electric field distribution; gate length; high gate voltage; integration degree reduction; low static power consumption; silicon layer thickness; sub-threshold swing; threshold voltage model; two-dimensional Possion equations; Lead; Logic gates; Silicon; DG p-IMOS; avalanche breakdown; threshold voltage;
Conference_Titel :
Electron Devices and Solid-State Circuits (EDSSC), 2013 IEEE International Conference of
Conference_Location :
Hong Kong
DOI :
10.1109/EDSSC.2013.6628110
