Abstract: An EEPROM cell is described which includes a trench formed in the field oxide adjacent to the EEPROM cell. Both the control gate and the floating gate of the cell are formed over this trench. By forming both gates above the trench, the capacitive coupling between the gates is increased. Thus a EEPROM cell constructed in accordance with the teachings of this invention may be constructed using a smaller surface area of the integrated circuit or may utilize a smaller programming voltage to charge and discharge the floating gate.

Abstract: The dielectric between the floating gate and the control gate, in an EEPROM or other floating gate memory is made by forming an oxide/nitride stack over the (first polysilicon) control gate. This dielectric not only provides a very high specific capacitance, which is desired to provide tight coupling of the control to the floating gate, but also provides excellent dielectric integrity. Moreover, the thickness of this dielectric layer does not exhibit any uncontrolled increase during exposure to second gate oxidation. Thus, the polysilicon-to-polysilicon dielectric is not only of high specific capacitance and high integrity, it is also very uniform.

Abstract: The dielectric between the floating gate and the control gate, in an EEPROM or other floating gate memory is made by forming an oxide/nitride stack over the (first polysilicon) control gate. This dielectric not only provides a very high specific capacitance, which is desired to provide tight coupling of the control to the floating gate, but also provides excellent dielectric integrity. Moreover, the thickness of this dielectric layer does not exhibit any uncontrolled increase during exposure to second gate oxidation. Thus, the polysilicon-to-polysilicon dielectric is not only of high specific capacitance and high integrity, it is also very uniform.

Abstract: Using a method according to one embodiment of the present invention, an EPROM array may be fabricated providing a dense EPROM array.First the polycrystalline silicon floating gates are formed and partially patterned on the surface of a substrate. A thin thermally grown oxide layer is then formed over the entire array. The source/drain regions are then implanted through the thin silicon dioxide layer into the substrate. Next a thick silicon dioxide layer is deposited by chemical vapor deposition on the surface of the array. The surface of the array is then coated with photoresist which, because of its nature, provides a planarized surface on the top layer of photoresist. The photoresist and the silicon dioxide layer are then etched using an etching process which provides an etching ratio of 1 to 1 between photoresist and silicon dioxide. The photoresist is completely etched away thus leaving the planarized silicon dioxide surface.