Abstract: A method for forming a CMOS integrated circuit device, the method including; providing a semiconductor substrate, forming a gate layer overlying the semiconductor substrate, patterning the gate layer to form NMOS and PMOS gate structures including edges; forming a first dielectric layer overlying the NMOS and PMOS gate structures to protect the NMOS and PMOS gate structures including the edges, forming a first masking layer overlying a first region adjacent the NMOS gate structure; etching a first source region and a first drain region adjacent to the PMOS gate structure using the first masking layer as a protective layer for the first region adjacent the NMOS gate structure, and depositing a silicon germanium material into the first source and drain regions to cause the channel region between the first source and drain regions of the PMOS gate structure to be strained in a compressive mode.

Abstract: A microstrip patch antenna including a ground plane base, an L-shaped feed structure and a laminate structure is disclosed herein. A matching network is formed by a clearance member of the laminate structure around a pin and a stub of the L-shaped feed structure on the bottom surface in which the clearance member around the pin effectively decreases shunt inductance and reduces a series capacitance at a feed point to enable a 50 ohm wideband operation.

Abstract: A microstrip patch antenna including a ground plane base, an L-shaped feed structure and a laminate structure is disclosed herein. A matching network is formed by a clearance member of the laminate structure around a pin and a stub of the L-shaped feed structure on the bottom surface in which the clearance member around the pin effectively decreases shunt inductance and reduces a series capacitance at a feed point to enable a 50 ohm wideband operation.

Abstract: A CMOS semiconductor integrated circuit device includes an NMOS device comprising a gate region, a source region, and a drain region and an NMOS channel region formed between the source region and drain region. A silicon carbide material is formed within the source region and formed within the drain region. The silicon carbide material causes the channel region to be in a tensile mode. The CMOS device also has a PMOS device comprising a gate region, a source region, and a drain region. The PMOS device has a PMOS channel region formed between the source region and the drain region. A silicon germanium material is formed within the source region and formed with in the drain region. The silicon germanium material causes the channel region to be in a compressive mode.

Abstract: A method and device for improved salicide resistance in polysilicon gates under 0.20 ?m. The several embodiments of the invention provide for formation of gate electrode structures with recessed and partially recessed spacers. One embodiment, provides a gate electrode structure with recessed thick inner spacers and thick outer spacers. Another embodiment provides a gate electrode structure with recessed thin inner spacers and recessed thick outer spacers. Another embodiment provides a gate electrode structure with thin inner spacers and partially recessed outer spacers. Another embodiment provides a gate electrode structure with two spacer stacks. The outermost spacer stack with recessed thin inner spacers and recessed thick outer spacers. The inner spacer stack within inner spacers and thin outer spacers. Another embodiment provides a gate electrode structure with two spacer stacks. The outermost spacer stack with recessed thin inner spacers and recessed thick outer spacers.

Abstract: A CMOS semiconductor integrated circuit device. The CMOS device includes an NMOS device comprising a gate region, a source region, and a drain region and an NMOS channel region formed between the source region and drain region. A silicon carbide material is formed within the source region and formed within the drain region. The silicon carbide material causes the channel region to be in a tensile mode. The CMOS device also has a PMOS device comprising a gate region, a source region, and a drain region. The PMOS device has a PMOS channel region formed between the source region and the drain region. A silicon germanium material is formed within the source region and formed with in the drain region. The silicon germanium material causes the channel region to be in a compressive mode.

Abstract: A semiconductor fabrication method or process is provided for fabricating an integrated circuit (IC) originally having an Al backend design using a Cu BEOL fabrication process. The method converts the Al backend design to a Cu backend design without redesigning the IC for Cu BEOL fabrication process, and uses the resultant Cu design to fabricate the IC using Cu BEOL fabrication process. The Al-Cu conversion first determines layer construction of the Al design, and then matches metal resistances of the Al design with metal resistances of a Cu design, matches intra-metal capacitances of the Al design with intra-metal capacitances of the Cu design, and matches inter-metal capacitance of the Al design with inter-metal capacitances of the Cu design.

Abstract: A method for processing IC designs for different metal BEOL processes is provided for enabling fabricating using a metal fabrication process an IC originally having a backend design for a different metal fabrication process. The method first determines layer constructions of an original design of an IC for a first metal backend process, and, based on the layer constructions of the original design of the IC, constructs primitive layer constructions of a target design of the IC for a second metal backend process. The method then tunes an effective dielectric constant of a dielectric layer of the target design to match an associated capacitance of the target backend design with a corresponding capacitance of the original backend design. The method can be used to convert a backend design of an IC from an old metal process (such as Al process) to a new metal process (such as Cu process), without redesigning the IC for the new metal BEOL fabrication process.

Abstract: A bio-sensor that includes (a) an optical fiber in which the surface of the fiber comprises a hydrogel polymer that includes a functional group comprising a first member of a binding pair; and (b) an excitation light source coupled to the fiber. When the fiber contacts a solution comprising a second member of the binding pair labeled with a light-emitting label, the first member binds to the second member, resulting in the emission of a detectable signal. Alternatively, the first member of the binding pair is provided with the light-emitting label.

Abstract: A method and device for improved salicide resistance in polysilicon gates under 0.20 &mgr;m. The several embodiments of the invention provide for formation of gate electrode structures with recessed and partially recessed spacers. One embodiment, provides a gate electrode structure with recessed thick inner spacers and thick outer spacers. Another embodiment provides a gate electrode structure with recessed thin inner spacers and recessed thick outer spacers. Another embodiment provides a gate electrode structure with thin inner spacers and partially recessed outer spacers. Another embodiment provides a gate electrode structure with two spacer stacks. The outermost spacer stack with recessed thin inner spacers and recessed thick outer spacers. The inner spacer stack with thin inner spacers and thin outer spacers. Another embodiment provides a gate electrode structure with two spacer stacks. The outermost spacer stack with recessed thin inner spacers and recessed thick outer spacers.