Abstract: Methods of forming a microelectronic structure are described. Those methods comprise providing a substrate comprising source/drain and gate regions, wherein the gate region comprises a metal layer disposed on a gate dielectric layer, and then laser annealing the substrate.

Abstract: A semiconductor device comprising a semiconductor body having a top surface and a first and second laterally opposite sidewalls as formed on an insulating substrate. A gate dielectric is formed on the top surface of the semiconductor body and on the first and second laterally opposite sidewalls of the semiconductor body. A gate electrode is then formed on the gate dielectric on the top surface of the semiconductor body and adjacent to the gate dielectric on the first and second laterally opposite sidewalls of the semiconductor body. The gate electrode comprises a metal film formed directly adjacent to the gate dielectric layer. A pair of source and drain regions are uniformed in the semiconductor body on opposite sides of the gate electrode.

Abstract: A method for making a semiconductor device is described. That method comprises forming a hard mask and an etch stop layer on a patterned sacrificial gate electrode layer. After first and second spacers are formed on opposite sides of that patterned sacrificial layer, the patterned sacrificial layer is removed to generate a trench that is positioned between the first and second spacers. At least part of the trench is filled with a metal layer.

Abstract: The present invention relates to the deposition of a layer above a transistor structure, causing crystalline stress within the transistor, and resulting in increased performance. The stress layer may be formed above a plurality of transistors formed on a substrate, or above a plurality of selected transistors.

Abstract: A semiconductor device and a method for forming it are described. The semiconductor device comprises a metal NMOS gate electrode that is formed on a first part of a substrate, and a silicide PMOS gate electrode that is formed on a second part of the substrate.

Abstract: Methods and associated structures of forming a microelectronic device are described. Those methods comprise providing a substrate comprising a first transistor structure comprising an n-type gate material and second transistor structure comprising a p-type gate material, selectively removing the n-type gate material to form a recess in the first gate structure, and then filling the recess with an n-type metal gate material.

Abstract: Numerous embodiments of a method for highly selective faceting of the S/D regions in a CMOS device are described. In one embodiment, source/drain regions are formed on a substrate. The source/drain regions are wet etched to form faceted regions. A silicon germanium layer is formed on the faceted regions of the source/drain regions to yield a strained device.

Abstract: A method for making a semiconductor device is described. That method comprises forming a dummy dielectric layer that is at least about 10 angstroms thick on a substrate, and forming a sacrificial layer on the dummy dielectric layer. After removing the sacrificial layer and the dummy dielectric layer to generate a trench that is positioned between first and second spacers, a gate dielectric layer is formed on the substrate at the bottom of the trench, and a metal layer is formed on the gate dielectric layer.

Abstract: A method is described for providing a nanostructure suspended above a substrate surface. The method includes providing a nanostructure encased in an oxide shell on a substrate and depositing a sacrificial material and a support material over the oxide encased nanostructure. Then, the sacrificial material is removed to expose the oxide encased nanostructure. Once the oxide encased nanostructure has been exposed, the oxide shell is removed from the oxide encased nanostructure such that the nanostructure is suspended above the substrate surface.

Abstract: A semiconductor based structure containing substantially smoothed waveguides having a rounded surface is disclosed, as well as methods of fabricating such a structure. The substantially smoothed waveguides may be formed of waveguide materials such as amorphous silicon or stoichiometric silicon nitride. The substantially smoothed waveguides are formed with an isotropic wet etch combined with sonic energy.

Abstract: A high-K thin film patterning solution is disclosed to address structural and process limitations of conventional patterning techniques. Subsequent to formation of gate structures adjacent a high-K dielectric layer, a portion of the high-K dielectric layer material is reduced, preferably via exposure to hydrogen gas, to form a reduced portion of the high-K dielectric layer. The reduced portion may be selectively removed utilizing wet etch chemistries to leave behind a trench of desirable geometric properties.

Abstract: A method for etching a metal layer is described. That method comprises forming a metal layer on a substrate, then exposing part of the metal layer to a wet etch chemistry that comprises an active ingredient with a diameter that exceeds the thickness of the metal layer.

Abstract: A method for making a semiconductor device is described. That method comprises forming a dielectric layer on a substrate, and forming a first metal layer on a first part of the dielectric layer, leaving a second part of the dielectric layer exposed. After a second metal layer is formed on both the first metal layer and the second part of the dielectric layer, a masking layer is formed on the second metal layer.

Abstract: A dielectric deposited on a substrate may be exposed to a salt solution. While exposed to the salt solution, an oxide is deposited on the dielectric.

Abstract: An epitaxially deposited source/drain extension may be formed for a metal oxide semiconductor field effect transistor. A sacrificial layer may be formed and etched away to undercut under the gate electrode. Then a source/drain extension of epitaxial silicon may be deposited to extend under the edges of the gate electrode. As a result, the extent by which the source/drain extension extends under the gate may be controlled by controlling the etching of the sacrificial material. Its thickness and depth may be controlled by controlling the deposition process. Moreover, the characteristics of the source/drain extension may be controlled independently of those of the subsequently formed deep or heavily doped source/drain junction.

Abstract: A method for selectively etching metal and metal-based films during integrated circuit fabrication. For one embodiment known chelators, which may be in relatively high concentration are used to etch metal films. In various alternative embodiments new chelators, developed by tailoring known chelators to target specific metals, are used to etch metal films. A metallic film is deposited on a substrate, the metallic film containing one or more specific metals. A layer of photoresist is deposited on the metallic film and patterned to mask a desired portion of the metallic film while exposing an undesired portion of the metallic film. One or more chelating agents are selected based upon the one or more specific metals contained in the metallic film and used to remove the undesired portion of the metallic film.

Abstract: A method for making a semiconductor device is described. That method comprises forming a high-k gate dielectric layer on a substrate, and modifying a first portion of the high-k gate dielectric layer to ensure that it may be removed selectively to a second portion of the high-k gate dielectric layer.

Abstract: A method for making a semiconductor device is described. That method comprises forming a metal oxide layer on a substrate, converting at least part of the metal oxide layer to a metal layer; and oxidizing the metal layer to generate a metal oxide high-k gate dielectric layer.

Abstract: At least a p-type and n-type semiconductor device deposited upon a semiconductor wafer containing metal or metal alloy gates. More particularly, a complementary metal-oxide-semiconductor (CMOS) device is formed on a semiconductor wafer having n-type and p-type metal gates.

Abstract: A hard mask may be formed and maintained over a polysilicon gate structure in a metal gate replacement technology. The maintenance of the hard mask, such as a nitride hard mask, may protect the polysilicon gate structure 14 from the formation of silicide or etch byproducts. Either the silicide or the etch byproducts or their combination may block the ensuing polysilicon etch which is needed to remove the polysilicon gate structure and to thereafter replace it with an appropriate metal gate technology.