Abstract: Integrated circuits suitable for high-performance applications, especially mixed signal products that have analog and digital sections, are fabricated from a semiconductor structure in which lower buried regions of opposite conductivity types are situated along a lower semiconductor interface between a semiconductive substrate and an overlying lower semiconductive layer. An upper buried region of a selected conductivity type is situated along an upper semiconductor interface between the lower semiconductive layer and an overlying upper semiconductive layer. Another upper buried region of opposite conductivity type to the first-mentioned upper buried region is preferably situated along the upper semiconductor interface. The upper semiconductive layer contains P-type and N-type device regions in which transistor zones are situated. The semiconductor structure is configured so that at least one of each of the P-type and N-type device regions is electrically isolated from the substrate.

Abstract: Integrated circuits suitable for high-performance applications, especially mixed signal products that have analog and digital sections, are fabricatable from a semiconductor structure having two levels of buried regions. In a typical embodiment lower buried regions of opposite conductivity types are situated along a lower semiconductor interface between a semiconductive substrate and an overlying lower semiconductive layer. Upper buried regions of opposite conductivity type are similarly situated along an upper semiconductor interface between the lower semiconductive layer and an overlying upper semiconductive layer. The upper semiconductive layer contains P-type and N-type device regions in which transistor zones are situated. The semiconductor structure is normally configured so that at least one of each of the P-type and N-type device regions is electrically isolated from the substrate. Complementary bipolar transistors can be integrated with complementary field-effect transistors in the structure.

Abstract: An EEPROM cell is formed in an IC chip by using only three masking steps in addition to those required for the basic CMOS transistors in the chip. A first mask layer is used to define source/drain regions of select and memory transistors within the EEPROM cell; a second mask layer is used to define a tunneling region of the memory transistor; and a third mask layer is used to define a floating gate of the memory transistor and a gate of the select transistor. A control gate of the memory transistor is formed using the same mask that is used to define the gates of the CMOS transistors. The third and fourth mask layers may also be used to form the lower and upper electrodes, respectively, of a capacitor.

Abstract: An EEPROM cell is formed in an IC chip by using only three masking steps in addition to those required for the basic CMOS transistors in the chip. A first mask layer is used to define source/drain regions of select and memory transistors within the EEPROM cell; a second mask layer is used to define a tunneling region of the memory transistor;and a third mask layer is used to define a floating gate of the memory transistor and a gate of the select transistor. A control gate of the memory transistor is formed using the same mask that is used to define the gates of the CMOS transistors. The third and fourth mask layers may also be used to form the lower and upper electrodes, respectively, of a capacitor.

Abstract: A method and structure for forming in an EEPROM memory transistor a tunnel dielectric region having an extremely small surface area. A floating gate region is formed in the conventional manner above a gate dielectric layer. The drain region is exposed utilizing photolithographic techniques and the gate dielectric removed therefrom. A thin layer of tunnel dielectric is then formed on the exposed drain region. A thin layer of polycrystalline silicon is then formed and etched in order to create very narrow floating gate extensions of polycrystalline silicon along the edge of the previously formed floating gate. The floating gate extension formed in this manner which overlies the drain region is separated from the drain region by thin tunnel dielectric. A dielectric is then formed on the device in order to provide a dielectric over the drain region which has a greater thickness than the tunnel dielectric underlying the floating gate extension.