Abstract: Methods of fabricating halo regions are provided. In one aspect, a method is provided of fabricating a first halo region and a second halo region for a circuit device of a first conductivity type and having a gate structure with first and second sidewalls. The first halo region of a second conductivity type is formed by implanting the substrate with impurities in a first direction toward the first sidewall of the gate structure. The second halo region of the second conductivity type is formed by implanting the substrate with impurities in a second direction toward the second sidewall of the gate structure. The first and second halo regions are formed without implanting impurities in a direction substantially perpendicular to the first and second directions.

Abstract: A method for fabricating a body-tied SOI transistor with reduced body resistance is presented. During the wafer fabrication process, a semiconductor wafer is placed in an ion implantation device and oriented to a first position relative to a beam path of the ion implantation device in order to obtain a substantially non-orthogonal twist orientation between the beam path and the transistor gate edge. Following this orientation of the first position, an ion species is implanted into a first implantation region. The wafer is then rotated to a second substantially non-orthogonal twist orientation, where another ion implantation is conducted. This process continues in the same manner, such that further substantially non-orthogonal twists and ion implantations are conducted, until the desired number of implantation areas is created. Halo or pocket implants are an example of the type of implantations to which the technique may be applied.

Abstract: For characterizing bulk leakage current of a junction, a center junction surrounded by an isolation structure is formed with a first depth. In addition, at least one periphery junction having a second depth greater than the first depth is formed in a portion of the center junction adjacent the isolation structure. A junction silicide is formed with the center and periphery junctions. The magnitude of a reverse-bias voltage across the junction silicide and the P-well is incremented for determining a critical magnitude of the reverse-bias when current through the junction silicide and the P-well reaches a threshold current density.

Abstract: A method for fabricating sidewall spacers in the manufacture of an integrated circuit device is disclosed. A dielectric spacer layer is formed over the semiconductor substrate. The dielectric spacer layer is etched prior to forming a layer subsequent to the dielectric layer, to form an L-shaped spacer. In another embodiment, a structure is formed on a substrate, the structure having a sidewall portion that is substantially orthogonal to a surface of the substrate. A dielectric layer is formed over the substrate. A spacer is formed over a portion of the dielectric layer and adjacent to the sidewall portion of the structure, wherein at least a portion of the dielectric layer over the substrate without an overlying oxide spacer is an unprotected portion of the dielectric. At least a part of the unprotected portion of the dielectric layer is removed. An intermediate source-drain region can be formed beneath a portion of the L-shaped spacer by controlling the thickness and/or the source drain doping levels.

Abstract: A method for fabricating a body-tied SOI transistor with reduced body resistance is presented. During the wafer fabrication process, a semiconductor wafer is placed in an ion implantation device and oriented to a first position relative to a beam path of the ion implantation device in order to obtain a substantially non-orthogonal twist orientation between the beam path and the transistor gate edge. Following this orientation of the first position, an ion species is implanted into a first implantation region. The wafer is then rotated to a second substantially non-orthogonal twist orientation, where another ion implantation is conducted. This process continues in the same manner, such that further substantially non-orthogonal twists and ion implantations are conducted, until the desired number of implantation areas is created. Halo or pocket implants are an example of the type of implantations to which the technique may be applied.

Abstract: A method of forming a semiconductor device provides a gate electrode on a substrate and forms a polysilicon reoxidation layer over the substrate and the gate electrode. A nitride layer is deposited over the polysilicon reoxidation layer and anisotropically etched The etching stops on the polysilicon reoxidation layer, with nitride offset spacers being formed on the gate electrode. The use of the polysilicon reoxidation layer as an etch stop layer prevents the gouging of the silicon substrate underneath the nitride layer, while allowing the offset spacers to be formed.

Abstract: The present invention relates to a method for fabricating MOS transistors with reduced parasitic capacitance. The present invention is based upon recognition that the parasitic capacitance of MOS transistors, such as are utilized in the manufacture of CMOS and IC devices, can be reduced by use of sidewall spacers having an optimized cross-sectional shape, in conjunction with an overlying insulator layer comprised of a low-k dielectric material.