Abstract: A memory cell for an EEPROM memory is fabricated to provide increased oxide thickness at the edge of the tunnel oxide and under the edges of the polysilicon capacitor plate in order to improve the dielectric integrity of the capacitor structure. In one embodiment using a silicided polysilicon process, the oxide is made thicker at the edge of the tunnel oxide by reoxidizing the silicon at the corner of the polysilicon capacitor plate and the underlying substrate surface by exposing the device to a short duration oxidation step after having deposited a 200 Å to 500 Å thick porous oxide over the device to protect the silicide from excessive exposure to the oxidizing ambient. In another embodiment the tunnel oxide is grown in a window in the gate oxide layer, which is about four times thicker than the tunnel oxide, so that the gate oxide completely surrounds the tunnel oxide, and the polysilicon capacitor plate extends beyond the edge of the tunnel oxide terminating at a point above the gate oxide.

Abstract: A memory cell for an EEPROM memory is fabricated to provide increased oxide thickness at the edge of the tunnel oxide and under the edges of the polysilicon capacitor plate in order to improve the dielectric integrity of the capacitor structure. In one embodiment using a silicided polysilicon process, the oxide is made thicker at the edge of the tunnel oxide by reoxidizing the silicon at the corner of the polysilicon capacitor plate and the underlying substrate surface by exposing the device to a short duration oxidation step after having deposited a 200 Å to 500 Å thick porous oxide over the device to protect the silicide from excessive exposure to the oxidizing ambient. In another embodiment the tunnel oxide is grown in a window in the gate oxide layer, which is about four times thicker than the tunnel oxide, so that the gate oxide completely surrounds the tunnel oxide, and the polysilicon capacitor plate extends beyond the edge of the tunnel oxide terminating at a point above the gate oxide.

Abstract: A high performance CMOS process using grown field oxide for active area isolation takes advantage of process steps used in LDD transistor fabrication to reduce the chip space occupied by the field oxide. Portions of the spacer oxide layer are retained intact over the field oxide during the etching step used to form the oxide spacers on the sides of the polysilicon gates. The retained spacer oxide portions increase the total oxide thickness in the field area to effectively block the ion implantation used to form the heavily doped portions of the source and drain regions. This enables use, in the initial fabrication steps, of a grown field oxide of reduced thickness and advantageously a correspondingly reduced width so as to reduce the chip space allocated to the field oxide.

Abstract: A memory cell for an EEPROM memory is fabricated to provide increased oxide thickness at the edge of the tunnel oxide and under the edges of the polysilicon capacitor plate in order to improve the dielectric integrity of the capacitor structure. In one embodiment using a silicided polysilicon process, the oxide is made thicker at the edge of the tunnel oxide by reoxidizing the silicon at the corner of the polysilicon capacitor plate and the underlying substrate surface by exposing the device to a short duration oxidation step after having deposited a 200 .ANG. to 500 .ANG. thick porous oxide over the device to protect the silicide from excessivie exposure to the oxidizing ambient. In another embodiment the tunnel oxide is grown in a window in the gate oxide layer, which is about four times thicker than the tunnel oxide, so that the gate oxide completely surrounds the tunnel oxide, and the polysilicon capacitor plate extends beyond the edge of the tunnel oxide terminating at a point above the gate oxide.