Abstract: Isolation structures having trenches formed on both sides of a LOCOS structure are disclosed. A semiconductor structure pad oxide layer is enlarged by local oxidation of silicon to form a field oxide. An etchback causes the thinnest portions of the field oxide to recede, such that a portion of the semiconductor substrate is exposed. An etch, through the exposed portion of the semiconductor substrate, forms a microtrench between the field oxide and the nitride layer with a lateral dimension that is less than that currently achievable by conventional photolithography. In another embodiment, formation of the microtrench is carried out as set forth above, but the nitride layer is immediately removed following trench formation. Alternatively, the pad oxide layer is stripped and a new oxide layer is regrown that substantially covers all exposed surfaces of active areas of the semiconductor substrate.

Abstract: A method of forming an isolation structure comprising forming n-type areas and/or p-type areas implanted respectively therein on a first surface of a substrate. A pad oxide film is grown on the first surface of the substrate covering the p-wells and/or n-wells. A diffusion barrier(s) is deposited on the first surface of the substrate and a second surface of the substrate to form an encapsulated structure. The encapsulated structure is annealed to activate the n-type and/or p-type areas. A mask material is applied over the diffusion barrier on the first surface of the substrate to define active device areas and a dry etch process is used to etch away the unmasked potions of the diffusion barrier. The mask material is stripped and a field oxide is grown on the first surface of the substrate. A portion of the field oxide and all of the diffusion barrier is removed, resulting in active areas surrounded by a field isolation structure.

Abstract: A barrier layer comprising silicon mixed with an impurity is disclosed for protection of gate dielectrics in integrated transistors. In particular, the barrier layer comprises silicon incorporating nitrogen. The nitrogen can be incorporated into an upper portion of the gate polysilicon during deposition, or a silicon layer doped with nitrogen after silicon deposition. The layer is of particular utility in conjunction with CVD tungsten silicide straps.

Abstract: Optimizing printing of an image from an alternating phase shifting mask having a phase shift error is accomplished using off-axis illumination. By simulating the image using varying off-axis illumination parameters, optimized parameters are selected to compensate for the phase shift error. Once the off-axis illumination parameters are optimized, the image is shot. In addition, the method of varying off-axis illumination parameters to compensate for a phase shift error permits an alternating phase shifting mask to be shot at two different wavelengths.

Abstract: A barrier layer comprising silicon mixed with an impurity is disclosed for protection of gate dielectrics in integrated transistors. In particular, the barrier layer comprises silicon incorporating nitrogen. The nitrogen can be incorporated into an upper portion of the gate polysilicon during deposition, or a silicon layer doped with nitrogen after silicon deposition. The layer is of particular utility in conjunction with CVD tungsten silicide straps.

Abstract: A semiconductor structure pad oxide layer is enlarged by local oxidation of silicon to form a field oxide. An etchback causes the thinnest portions of the field oxide to recede such that a portion of the semiconductor substrate is exposed. An etch through the exposed portion of the semiconductor substrate forms a microtrench between the field oxide and the nitride layer with a lateral dimension that is less than that currently achievable by conventional photolithography. The microtrench is then filled by oxide or nitride growth or by deposition of a dielectric material. In another embodiment, formation of the microtrench is carried out as set forth above, but the nitride layer is removed immediately following trench formation. Alternatively, the pad oxide layer is stripped and a new oxide layer is regrown that substantially covers all exposed surfaces of active areas of the semiconductor substrate.

Abstract: A field isolation process performed on a silicon wafer is carried out by high pressure oxidation. Using oxygen rather than water vapor as the oxidant substantially eliminates nitride inclusions via the Kooi effect. Preferred high pressure field oxidation processes simplify all CMOS flows by eliminating the need for sacrificial oxide growth and removal steps.

Abstract: A semiconductor structure pad oxide layer is enlarged by local oxidation of silicon to form a field oxide. An etchback causes the thinnest portions of the field oxide to recede such that a portion of the semiconductor substrate is exposed. An etch through the exposed portion of the semiconductor substrate forms a microtrench between the field oxide and the nitride layer with a lateral dimension that is less than that currently achievable by conventional photolithography. The microtrench is then filled by oxide or nitride growth or by deposition of a dielectric material. In another embodiment, formation of the microtrench is carried out as set forth above, but the nitride layer is removed immediately following trench formation. Alternatively, the pad oxide layer is stripped and a new oxide layer is regrown that substantially covers all exposed surfaces of active areas of the semiconductor substrate.

Abstract: A barrier layer comprising silicon mixed with an impurity is disclosed for protection of gate dielectrics in integrated transistors. In particular, the barrier layer comprises silicon incorporating nitrogen. The nitrogen can be incorporated into an upper portion of the gate polysilicon during deposition, or a silicon layer doped with nitrogen after silicon deposition. The layer is of particular utility in conjunction with CVD tungsten silicide straps.

Abstract: A method of forming isolation structures in semiconductor substrates comprising exposing a region of the semiconductor simultaneously to a transforming agent and to a viscosity reducing agent so that the transforming agent transforms a portion of the substrate into an isolation structure and the viscosity reducing agent reduces the viscosity of the isolation structure during formation. In one embodiment, a silicon substrate is exposed to oxygen in the presence of fluorine so that a silicon oxide isolation region is formed. The fluorine reduces the viscosity of the silicon oxide isolation region during formation which results in less lateral, bird's beak encroachment under adjacent masking stacks and also results in lower internal stress in the isolation region during formation. The lower internal stress and the lessened lateral encroachment result in thicker and improved isolation regions.

Abstract: A method of forming isolation structures in semiconductor substrates comprising exposing a region of the semiconductor simultaneously to a transforming agent and to a viscosity reducing agent so that the transforming agent transforms a portion of the substrate into an isolation structure and the viscosity reducing agent reduces the viscosity of the isolation structure during formation. In one embodiment, a silicon substrate is exposed to oxygen in the presence of fluorine so that a silicon oxide isolation region is formed. The fluorine reduces the viscosity of the silicon oxide isolation region during formation which results in less lateral, bird's beak encroachment under adjacent masking stacks and also results in lower internal stress in the isolation region during formation. The lower internal stress and the lessened lateral encroachment result in thicker and improved isolation regions.

Abstract: A method of forming isolation structures in semiconductor substrates comprising exposing a region of the semiconductor simultaneously to a transforming agent and to a viscosity reducing agent so that the transforming agent transforms a portion of the substrate into an isolation structure and the viscosity reducing agent reduces the viscosity of the isolation structure during formation. In one embodiment, a silicon substrate is exposed to oxygen in the presence of fluorine so that a silicon oxide isolation region is formed. The fluorine reduces the viscosity of the silicon oxide isolation region during formation which results in less lateral, bird's beak encroachment under adjacent masking stacks and also results in lower internal stress in the isolation region during formation. The lower internal stress and the lessened lateral encroachment result in thicker and improved isolation regions.

Abstract: A barrier layer comprising silicon mixed with an impurity is disclosed for protection of gate dielectrics in integrated transistors. In particular, the barrier layer comprises silicon incorporating nitrogen. The nitrogen can be incorporated into an upper portion of the gate polysilicon during deposition, or a silicon layer doped with nitrogen after silicon deposition. The layer is of particular utility in conjunction with CVD tungsten silicide straps.

Abstract: A method of forming an isolation structure comprising forming n-type areas and/or p-type areas implanted respectively therein on a first surface of the substrate. A pad oxide film is grown on substrate first surface covering the p-wells and/or n-wells. A diffusion barrier(s) is deposited on the substrate first surface and a substrate second surface to form an encapsulated structure. The encapsulated structure is annealed to activate the n-type and/or p-type areas. A mask material is applied over the diffusion barrier on the substrate first surface to define active device areas and a dry etch process is used to etch away the unmasked portions of the diffusion barrier. The mask material is stripped and a field oxide is grown on the substrate first surface. A portion of the field oxide and all of the diffusion barrier is removed, resulting in active areas surrounded by a field isolation structure.

Abstract: A barrier layer comprising silicon mixed with an impurity is disclosed for protection of gate dielectrics in integrated transistors. In particular, the barrier layer comprises silicon incorporating nitrogen. The nitrogen can be incorporated into an upper portion of the gate polysilicon during deposition, or a silicon layer doped with nitrogen after silicon deposition. The layer is of particular utility in conjunction with CVD tungsten silicide straps.

Abstract: Methods for forming self-aligned photosensitive material spacers about protruding structures in semiconductor devices. One embodiment of the invention is a method for forming a LDD structure, utilizing disposable photosensitive material spacers. A second embodiment of the invention includes a method for forming a transistor, having salicided source/drain regions, utilizing photosensitive polyimide spacers for forming the salicided source/drain regions, without disposing of the spacers. A third embodiment of the invention includes a method for creating an offset from a protruding structure on a semiconductor substrate, using disposable photosensitive material spacers.

Abstract: A method for forming a photomask including applying photoresist to a semiconductor substrate, exposing a first area of the photoresist to a first dosage of radiation, and exposing a second area of the photoresist to a second dosage of radiation. The first and second areas may be concurrently exposed. First and second regions of the photoresist are then removed to form first and second openings that have different depths in the photoresist. Such removal may be effected by developing the first and second areas of the photoresist. One of the openings may extend down to an insulating layer formed on the semiconductor substrate. A contact and/or trench etch may be performed to remove. a portion of the insulating layer. Conductive material may then be deposited in the opening so formed to form a contact, a via, or another electrically conductive element that communicates with a structure underlying the insulating layer.

Abstract: A method of forming isolation structures in semiconductor substrates comprising exposing a region of the semiconductor simultaneously to a transforming agent and to a viscosity reducing agent so that the transforming agent transforms a portion of the substrate into an isolation structure and the viscosity reducing agent reduces the viscosity of the isolation structure during formation. In one embodiment, a silicon substrate is exposed to oxygen in the presence of fluorine so that a silicon oxide isolation region is formed. The fluorine reduces the viscosity of the silicon oxide isolation region during formation which results in less lateral, bird's beak encroachment under adjacent masking stacks and also results in lower internal stress in the isolation region during formation. The lower internal stress and the lessened lateral encroachment result in thicker and improved isolation regions.

Abstract: A barrier layer comprising silicon mixed with an impurity is disclosed for protection of gate dielectrics in integrated transistors. In particular, the barrier layer comprises silicon incorporating nitrogen. The nitrogen can be incorporated into an upper portion of the gate polysilicon during deposition, or a silicon layer doped with nitrogen after silicon deposition. The layer is of particular utility in conjunction with CVD tungsten silicide straps.

Abstract: A method of forming isolation structures in semiconductor substrates comprising exposing a region of the semiconductor simultaneously to a transforming agent and to a viscosity reducing agent so that the transforming agent transforms a portion of the substrate into an isolation structure and the viscosity reducing agent reduces the viscosity of the isolation structure during formation. In one embodiment, a silicon substrate is exposed to oxygen in the presence of fluorine so that a silicon oxide isolation region is formed. The fluorine reduces the viscosity of the silicon oxide isolation region during formation which results in less lateral, bird's beak encroachment under adjacent masking stacks and also results in lower internal stress in the isolation region during formation. The lower internal stress and the lessened lateral encroachment result in thicker and improved isolation regions.