Title :
Modeling of bistable device I-V characteristic resulting from conductivity modulation in semiconductors
Author :
Son, Ilhun ; Tang, Ting-wei ; Navon, David H.
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., Massachusetts Univ., Amherst, MA, USA
fDate :
4/1/1988 12:00:00 AM
Abstract :
The bistable I-V characteristic in a silicon diode-like device structure that resembles the double-base diode is predicted by numerical solution. This bistable characteristic results from the conductivity modulation effect coupled with an ohmic voltage drop produced by the current through a shunt resistor. The back-surface field effect has a significant influence on the minority-carrier transport of this type of bistable I-V characteristic. A two-dimensional numerical simulation is performed to explore the steady-state bistable I-V characteristic including a negative dynamic conductance region. To better understand this mechanism, a DC equivalent circuit based on a one-dimensional current-flow model is proposed. The I-V characteristic obtained by this equivalent circuit agrees well with an exact two-dimensional numerical simulation result
Keywords :
elemental semiconductors; equivalent circuits; semiconductor device models; semiconductor diodes; silicon; DC equivalent circuit; Si; back-surface field effect; bistable device I-V characteristic; conductivity modulation in semiconductors; diode-like device structure; exact two-dimensional numerical simulation; minority-carrier transport; negative dynamic conductance region; one-dimensional current-flow model; predicted by numerical solution; semiconductors; shunt resistor; steady-state bistable I-V characteristic; two-dimensional numerical simulation; Conductivity; Contacts; Equivalent circuits; Numerical simulation; Semiconductor device modeling; Semiconductor diodes; Steady-state; Switches; Thyristors; Voltage;
Journal_Title :
Electron Devices, IEEE Transactions on
