Abstract: A method for forming a self-aligned, recessed channel, MOSFET device that alleviates problems due to short channel and hot carrier effects while reducing inter-electrode capacitance is described. A thin pad oxide layer is grown overlying the substrate and a gate recess, followed by deposition of a thick silicon nitride layer filling the gate recess. The top surface is planarized exposing the pad oxide layer. An additional oxide layer is grown, thickening the pad oxide layer. A portion of the silicon nitride layer is etched away and additional oxide layer is again grown. This forms a tapered oxide layer along the sidewalls of the gate recess. The remaining silicon nitride layer is removed. The oxide layer at the bottom of the gate recess is removed and a gate dielectric layer is grown. Gate polysilicon is deposited filling the gate recess. S/D implantations, metallization, and passivation complete fabrication of the device.

Abstract: A MOSFET includes a dielectric, preferably in the form of a metal thick oxide that extends alongside the MOSFET's drift region. A voltage across this dielectric between its opposing sides exerts an electric field into the drift region to modulate the drift region electric field distribution so as to increase the breakdown voltage of a reverse biased semiconductor junction between the drift region and body region. This allows for higher doping of the drift region, for a given breakdown voltage when compared to conventional MOSFETs.

Abstract: A MOSFET includes a dielectric, preferably in the form of a metal thick oxide that extends alongside the MOSFET's drift region. A voltage across this dielectric between its opposing sides exerts an electric field into the drift region to modulate the drift region electric field distribution so as to increase the breakdown voltage of a reverse biased semiconductor junction between the drift region and body region. This allows for higher doping of the drift region, for a given breakdown voltage when compared to conventional MOSFETs.

Abstract: A method for forming a self-aligned, recessed channel, MOSFET device that alleviates the problems due to short channel and hot carrier effects while reducing inter-electrode capacitance is described. A substrate with an active area encompassed by a shallow trench isolation (STI) region is provided. A mask oxide layer is then patterned and etched to expose the substrate and a portion of the STI region. The surface is etched and the mask oxide layer is eroded away while creating a gate recess in the unmasked area. A thin pad oxide layer is then grown overlying the surface followed by a deposition of a thick silicon nitride layer covering the surface and filling the gate recess. The top surface is planarized exposing the pad oxide layer. An additional oxide layer is grown causing the pad oxide layer to thicken. A portion of the silicon nitride layer is etched away and additional oxide layer is again grown causing the pad oxide layer to further thicken.

Abstract: A method for forming a self-aligned, recessed channel, MOSFET device that alleviates the problems due to short channel and hot carrier effects while reducing inter-electrode capacitance is described. A substrate with an active area encompassed by a shallow trench isolation (STI) region is provided. A mask oxide layer is then patterned and etched to expose the substrate and a portion of the STI region. The surface is etched and the mask oxide layer is eroded away while creating a gate recess in the unmasked area. A thin pad oxide layer is then grown overlying the surface followed by a deposition of a thick silicon nitride layer covering the surface and filling the gate recess. The top surface is planarized exposing the pad oxide layer. An additional oxide layer is grown causing the pad oxide layer to thicken. A portion of the silicon nitride layer is etched away and additional oxide layer is again grown causing the pad oxide layer to further thicken.