Title :
Gate tunneling current in thin oxide MOSFET
Author :
Karim, Mohammed Fakhrul ; Shaari, Sahbudin ; Majlis, Burhanuddin Yeop
Author_Institution :
Dept of Electr. Electron. & Syst. Eng., Univ. Kebangsaan, Malaysia
Abstract :
Quantum mechanical tunneling of electrical conduction in a thin insulating film (SiO2) from the strongly inverted Si surface has been studied. A simple method of calculating the penetration probability of the energetic electrons, and the tunneling current is proposed. These electrons are from a series of quantized energy levels in the potential well (assuming triangular nature), formed by the large bending of the silicon conduction band at the surface. Due to the down scaling of device dimensions, the field across the oxide becomes high enough, and causes a large band bending in the form of a narrow potential well. The gate oxide thickness and gate voltage dependence of the tunneling current are analyzed using the tunneling current model. This study may be helpful in predicting the oxide breakdown process
Keywords :
MOSFET; conduction bands; electric breakdown; insulating thin films; interface states; probability; semiconductor device models; semiconductor-insulator boundaries; silicon; surface states; tunnelling; Si conduction band; Si-SiO2; electrical conduction; gate oxide thickness; gate tunneling current; gate voltage dependence; large band bending; oxide breakdown process prediction; penetration probability; potential well; quantized energy levels; quantum mechanical tunneling; strongly inverted Si surface; thin insulating film; thin oxide MOSFET; tunneling current model; Conductive films; Dielectrics and electrical insulation; Electrons; Energy states; MOSFET circuits; Potential well; Probability; Quantum mechanics; Semiconductor films; Tunneling;
Conference_Titel :
Semiconductor Electronics, 1996. ICSE '96. Proceedings., 1996 IEEE International Conference on
Conference_Location :
Penang
Print_ISBN :
0-7803-3388-8
DOI :
10.1109/SMELEC.1996.616500
