Abstract: Disclosed is an integrated circuit with multiple semiconductor fins having different widths and variable spacing on the same substrate. The method of forming the circuit incorporates a sidewall image transfer process using different types of mandrels. Fin thickness and fin-to-fin spacing are controlled by an oxidation process used to form oxide sidewalls on the mandrels, and more particularly, by the processing time and the use of intrinsic, oxidation-enhancing and/or oxidation-inhibiting mandrels. Fin thickness is also controlled by using sidewalls spacers combined with or instead of the oxide sidewalls. Specifically, images of the oxide sidewalls alone, images of sidewall spacers alone, and/or combined images of sidewall spacers and oxide sidewalls are transferred into a semiconductor layer to form the fins. The fins with different thicknesses and variable spacing can be used to form a single multiple-fin FET or, alternatively, various single-fin and/or multiple-fin FETs.

Abstract: An inverse-T transistor is formed by a method that decouples the halo implant, the deep S/D implant and the extension implant, so that the threshold voltage can be set by adjusting the halo implant without being affected by changes to the extension implant that are intended to alter the series resistance of the device. Formation of the inverse-T structure can be made by a damascene method in which a temporary layer deposited over the layer that will form the cross bar of the T has an aperture formed in it to hold the gate electrode, the aperture being lined with vertical sidewalls that provide space for the ledges that form the T. Another method of gate electrode formation starts with a layer of poly, forms a block for the gate electrode, covers the horizontal surfaces outside the gate with an etch-resistant material and etches horizontally to remove material above the cross bars on the T, the cross bars being protected by the etch resistant material.

Abstract: A structure and apparatus is provided for an electrostatic discharge power clamp, for use with high voltage power supplies. The power clamp includes a network of transistor devices, for example, nFETs arranged in series between a power rail and a ground rail. The first transistor device is biased into a partially on-state, and thus, neither device sees the full voltage potential between the power rail and the ground rail. Accordingly, the power clamp can function in voltage environments higher than the native voltage of the transistor devices. Additionally, the second transistor device is controlled by an RC network functioning as a trigger which allows the second transistor device to turn on during a voltage spike such as occurs during an ESD event. The capacitor of the RC network may be small thereby requiring small real estate on the integrated circuit. The clamp may have fast turn-on times as well as conducting current for long periods of time after turning on.

Abstract: An integrated circuit amplifier includes, in an exemplary embodiment, a first field effect transistor (FET) device configured as a common source amplifier with source degeneration and a second FET device configured as a tunneling gate FET, the tunneling gate FET coupled to the source follower. The tunneling gate FET is further configured so as to set a transconductance of the amplifier and the common source amplifier with source degeneration is configured so as to set an output conductance of the amplifier.

Abstract: A method of forming a self-aligned SOI diode, the method comprising depositing a protective structure over a substrate; implanting a plurality of diffusion regions of variable dopant types in an area between at least one pair of isolation regions in the substrate, the plurality of diffusion regions separated by a diode junction, wherein the implanting aligns an upper surface of the diode junction with the protective structure; and removing the protective structure. The method further comprises forming a silicide layer over the diffusion regions and aligned with the protective structure. The protective structure comprises a hard mask, wherein the hard mask comprises a silicon nitride layer. Alternatively, the protective structure comprises a polysilicon gate and insulating spacers on opposite sides of the gate. Furthermore, in the removing step, the spacers remain on the substrate.

Abstract: A field effect transistor with associated parasitic lateral npn bipolar junction transistor includes a source region in a substrate, a channel region in the substrate laterally adjacent to the source region, a drain region in the substrate laterally adjacent to the channel region, and a gate above the channel region of the substrate. In addition, a reduced trigger voltage region of the substrate is positioned below the drain region. The reduced trigger voltage region has a threshold voltage of about zero and comprises an undoped region of the pure wafer substrate. Thus, the reduced trigger voltage region is free of implanted N-type and P-type doping.

Abstract: Disclosed is a method for increasing substrate resistance in a silicon controlled rectifier in order to decrease turn on time so that the silicon controlled rectifier may be used as an effective electrostatic discharge protection device to protect against HBM, MM and CDM discharge events. Additionally, disclosed is an improved SCR structure that is adapted for use as an electrostatic discharge device to protect against human body model events by delivering an electrostatic discharge current directly to a ground rail. The improved SCR structure incorporates various features for increasing substrate resistance and, thereby, for decreasing turn on time. These features include a second n-well that functions as an obstacle to current flow, a narrow current flow channel between co-planar buried n-bands connected to a lower portion of the second n-well, a zero threshold voltage area, and an external resistor electrically connected between the SCR and the ground rail.

Abstract: An inverse-T transistor is formed by a method that decouples the halo implant, the deep S/D implant and the extension implant, so that the threshold voltage can be set by adjusting the halo implant without being affected by changes to the extension implant that are intended to alter the series resistance of the device. Formation of the inverse-T structure can be made by a damascene method in which a temporary layer deposited over the layer that will form the cross bar of the T has an aperture formed in it to hold the gate electrode, the aperture being lined with vertical sidewalls that provide space for the ledges that form the T. Another method of gate electrode formation starts with a layer of poly, forms a block for the gate electrode, covers the horizontal surfaces outside the gate with an etch-resistant material and etches horizontally to remove material above the cross bars on the T, the cross bars being protected by the etch resistant material.