Abstract: An intergrated circuit drain extension transistor for sub micron CMOS processes. A transistor gate (40) is formed over a CMOS n-well region (80) and a CMOS p-well region (70) in a silicon substrate (10). Transistor source regions (50), (140) and drain regions (55), (145) are formed in the various CMOS well regions to form drain extension transistors where the CMOS well regions (70), (80) serve as the drain extension regions of the transistor.

Abstract: The present invention relates to an NMOS transistor structure which comprises a p-well region in a semiconductor substrate, an n-type source region in the p-well region, and an n-type drain region in the p-well region. The source and drain regions are laterally spaced apart from one another and define a p-type channel region therebetween in the p-well region. The NMOS transistor further comprises a gate having a gate electrode and a gate oxide overlying the channel region of the p-well region. A PDUF region underlies the p-well region and exhibits a resistivity which is less than the p-well region, wherein the PDUF region lowers a resistance associated with the p-well region at high drain voltages. The lowered resistance decreases a gain associated with a parasitic bipolar transistor and increases an injection induced breakdown voltage characteristic of the NMOS transistor structure.

Abstract: An electronic circuit (20), comprising a semiconductor substrate (22) and a first layer (30) in a fixed physical relation to the semiconductor substrate. The electronic circuit further comprises a well (32a) formed in the first layer, wherein the well comprises a first conductivity type and has a side dimension and a bottom dimension. The electronic circuit further comprises a first enclosure (34, 26) surrounding the side dimension and the bottom dimension of the well, wherein the first enclosure comprises a second conductivity type complementary of the first conductivity type and has a side dimension and a bottom dimension. The electronic circuit further comprises a second enclosure (32b, 24) surrounding the side dimension and the bottom dimension of the first enclosure, wherein the second enclosure comprises the first conductivity type.

Abstract: An electronic device architecture is described comprising a field effect device in an active region 22 of a substrate 10. Channel stop implant regions 28a and 28b are used as isolation structures and are spaced apart from the active region 22 by extension zones 27a and 27b. The spacing is established by using an inner mask layer 20 and an outer mask layer 26 to define the isolation structures.

Abstract: A P-channel floating-gate MOS transistor is used to detect and measure positive mobile ions in the oxide layers of a semiconductor device. The transistor is first "programmed" by applying a voltage close to the breakdown voltage of the transistor, which causes electrons to tunnel through the oxide underlying the floating gate and to become trapped on the floating gate. This results in a negative voltage on the floating gate, which turns the transistor on and causes a first current, I.sub.DS0 to flow through the transistor. The semiconductor device is then baked, or heated, to accelerate the movement of positive mobile ions attracted to the negative charge previously trapped on the floating gate. Any positive mobile ions collected by the floating gate will neutralize a portion of the negative charge on the floating gate and will create a less negative voltage on the floating gate, resulting in a lesser current through the device after the bake.