Abstract: An integrated circuit structure and a method of fabrication thereof are provided. In particular, fully planarized, trench isolated semiconductor regions, e.g. comprising doped polysilicon, are provided in an integrated circuit substrate. These polysilicon regions have a smooth surface, substantially coplanar with the substrate surface, provided by chemical mechanical polishing. The near zero topography substrate provides for formation thereon of integrated circuit structures including e.g. capacitors, resistors, thin film capacitors, and interconnects, in the polysilicon trench regions at the same process level as devices formed in the semiconductor substrate. Thus a simple and flexible process for formation of improved device structures is provided, compatible with known Bipolar, CMOS and Bipolar-CMOS processes.

Abstract: A integrated circuit structure and a method of fabrication thereof are provided. In particular, fully planarized, trench isolated semiconductor regions, e.g. comprising doped polysilicon, are provided in an integrated circuit substrate. These polysilicon regions have a smooth surface, substantially coplanar with the substrate surface, provided by chemical mechanical polishing. The near zero topography substrate provides for formation thereon of integrated circuit structures including e.g. capacitors, resistors, thin film capacitors, and interconnects, in the polysilicon trench regions at the same process level as devices formed in the semiconductor substrate. Thus a simple and flexible process for formation of improved device structures is provided, compatible with known Bipolar, CMOS and Bipolar-CMOS processes.

Abstract: A method is provided for forming a transistor for a bipolar, CMOS, or bipolar CMOS integrated circuit. The method is applicable to forming a double polysilicon self-aligned bipolar transistor using a single masking step for defining the emitter structure with a narrow emitter-base contact area and a large emitter contact area. The method comprises selectively providing a tapered body of dielectric to mask a region of the substrate on which an emitter is to be formed. A conductive layer is provided around the tapered body to form base contact electrodes. The tapered body is selectively removed from the substrate without damaging the underlying silicon substrate, to leave a tapered opening; localized dielectric isolation is provided in the form of sidewall spacers on the first conductive layer. The tapered opening is filled with a layer of a second conductive material to form a second electrode i.e. an emitter structure.

Abstract: A method is provided for forming a fully planarized trench isolated region in a semiconductor substrate for an integrated circuit, for example, a trench isolated field oxide region, or a trench isolated semiconductor region in which thin film semiconductor devices are formed. Planarization is accomplished by a chemical mechanical polishing process in which coplanar layers of a chemical mechanical polish resistant material are provided in a centre region of wide trenches as well as on the semiconductor substrate surface adjacent the trenches. The chemical mechanical polish resistant layer in the centre region of a wide trench forms an etch stop to prevent dishing of layers filling the trench during overall wafer planarization by chemical mechanical polishing. The method is compatible with CMOS, Bipolar and Bipolar CMOS processes for submicron VLSI and ULSI integrated circuit structures.

Abstract: A method is provided for forming multi-valued linear resistors for an integrated circuit using a single mask level. A plurality of trenches are defined in a substrate. Each trench has contact regions of a specific lateral dimension and a narrower portion extending therebetween. Successive conformal layers of a first dielectric layer, a first conductive layer of high resistivity and a second conductive layer of lower resistivity are provided to fill the trench. The amount of the second conductive layer which fills the trench depends on the width of the trench. The resulting structure is planarized, preferably by chemical-mechanical polishing to provide fully planarized topography. Advantageously when the first and second conductive layers are provided from layers of undoped and doped polysilicon respectively, the trench dimensions control the amount of dopant incorporated in each region of the trench.

Abstract: A method is provided for forming multi-valued linear resistors for an integrated circuit using a single mask level. A plurality of trenches are defined in a substrate. Each trench has contact regions of a specific lateral dimension and a narrower portion extending therebetween. Successive conformal layers of a first dielectric layer, a first conductive layer of high resistivity and a second conductive layer of lower resistivity are provided to fill the trench. The amount of the second conductive layer which fills the trench depends on the width of the trench. The resulting structure is planarized, preferably by chemical-mechanical polishing to provide fully planarized topography. Advantageously when the first and second conductive layers are provided from layers of undoped and doped polysilicon respectively, the trench dimensions control the amount of dopant incorporated in each region of the trench.

Abstract: A low temperature CVD method is provided for depositing high quality stoichiometric, poly-crystalline silicon carbide films and for depositing emitter quality, heavily doped silicon carbide films, suitable for application in silicon hetero-junction bipolar transistors. The process is compatible with bipolar-CMOS device processing and comprises pyrolysis of di-tert-butyl silane in an oxygen free ambient, with n-type doping provided by phosphorus source comprising tert-butyl phosphine. Advantageously oxygen is excluded from the reactant gas mixture and the method includes pre-cleaning the susbtrate with nitrogen trifluoride and passivating the silicon carbide film with fluorine species from nitrogen trifluoride.

Abstract: In an integrated circuit process a composite dielectric layer is formed on a monocrystalline, polycrystalline or amorphous silicon substrate by thermally growing a first silicon nitride layer from a surface layer of the silicon and then depositing a layer of amorphous or polycrystalline silicon. A second nitride layer is thermally grown from the deposited silicon to form a nitride-silicon-nitride, termed nitsinitride, composite dielectric. At least a top layer of the nitsinitride dielectric can be oxidized to produce an alternative composite dielectric, termed oxidized nitsinitride. Variation of the thickness of the dielectric layers and/or repeating the layering process sequence results in composite dielectrics of different thicknesses and dielectric properties.

Abstract: In a method and apparatus for plasma stripping a polymer photoresist coating from a semiconductor substrate, positively charged species are removed from an activated gas flow before the gas flow is brought into contact with the coating to strip the coating from the substrate. The positively charged species may be removed by bringing the activated gas into contact with a grounded conducting surface to discharge the positively charged species, or by passing the activated gas through a negatively charged electrostatic filter to filter out positively charged species. The removal of positively charged species from the gas flow reduces or eliminates build up of positive charge on an outer surface of the photoresist coating so as to avoid driving mobile positively charged ions from the photoresist into the substrate, thereby avoiding contamination of the substrate.

Abstract: In a method and apparatus for plasma stripping a polymer photoresist coating from a semiconductor substrate, ultraviolet radiation generated as a byproduct of plasma generation is absorbed by a baffle placed between a plasma source and the substrate. The baffle inhibits incidence of ultraviolet light on the substrate while permitting flow of activated gas onto the substrate to chemically strip the photoresist from the substrate. Use of the baffle reduces microscopic damage to the substrate.