A compact model for LDD MOSFET is proposed,which involves the hyperbolic tangent function description and the physics of device with emphasis on the substrate current modeling.The simulation results demonstrate good ...A compact model for LDD MOSFET is proposed,which involves the hyperbolic tangent function description and the physics of device with emphasis on the substrate current modeling.The simulation results demonstrate good agreement with measurement,and show that deep submicron LDD MOSFET has larger substrate current than submicron device does.The improved model costs low computation consumption,and is effective in manifestation of hot carrier effect and other effects in deep submicron devices,in turn is suitable for design and reliability analysis of scaling down devices.展开更多
The low voltage substrate current (Ib) has been studied based on generation kinetics and used as a monitor of interface states (Nit) generation for ultra-thin oxide n-MOSFETs under constant voltage stress. It is f...The low voltage substrate current (Ib) has been studied based on generation kinetics and used as a monitor of interface states (Nit) generation for ultra-thin oxide n-MOSFETs under constant voltage stress. It is found that the low voltage Ib is formed by electrons tunnelling through interface states, and the variations of Ib(△Ib) are proportional to variations of Nit (△Nit). The Nit energy distributions were determined by differentiating Nit(Vg). The results have been compared with that measured by using gate diode technique.展开更多
文摘A compact model for LDD MOSFET is proposed,which involves the hyperbolic tangent function description and the physics of device with emphasis on the substrate current modeling.The simulation results demonstrate good agreement with measurement,and show that deep submicron LDD MOSFET has larger substrate current than submicron device does.The improved model costs low computation consumption,and is effective in manifestation of hot carrier effect and other effects in deep submicron devices,in turn is suitable for design and reliability analysis of scaling down devices.
文摘The low voltage substrate current (Ib) has been studied based on generation kinetics and used as a monitor of interface states (Nit) generation for ultra-thin oxide n-MOSFETs under constant voltage stress. It is found that the low voltage Ib is formed by electrons tunnelling through interface states, and the variations of Ib(△Ib) are proportional to variations of Nit (△Nit). The Nit energy distributions were determined by differentiating Nit(Vg). The results have been compared with that measured by using gate diode technique.
