Abstract: A method for forming an extended metal gate without poly wrap around effects. A semiconductor structure is provided having a gate structure thereon. The gate structure comprising a gate dielectric layer, a gate silicon layer, a doped silicon oxide layer, and a disposable gate layer stacked sequentially. Spacers are foremed on the sidewalls of the gate structure. A dielectric gapfill layer is formed over the semiconductor structure and the gate structure and planarized, stopping on the disposable gate layer. A first silicon nitride layer is formed over the disposable gate layer, and a dielectric layer is formed over the first silicon nitride layer. The dielectric layer is patterned to form a trench over the gate structure; wherein the trench has a width greater than the width of the gate structure. The first silicon nitride layer in the bottom of the trench and the disposable gate layer are removed using one or more selective etching processes.

Abstract: A method for forming dual-damascene type conducting interconnects with nonmetallic barriers that protect said interconnects from fluorine out-diffusion from surrounding low-k, fluorinated dielectric materials. One embodiment of the method is particularly suited for forming such interconnects in microelectronics fabrications of the sub 0.15 micron generation.

Abstract: A method for forming dual-damascene type conducting interconnects with non-metallic barriers that protect said interconnects from fluorine out-diffusion from surrounding low-k, fluorinated dielectric materials. One embodiment of the method is particularly suited for forming such interconnects in microelectronics fabrications of the sub 0.15 micron generation.

Abstract: A method for forming dual-damascene type conducting interconnects with non-metallic barriers that protect said interconnects from fluorine out-diffusion from surrounding low-k, fluorinated dielectric materials. One embodiment of the method is particularly suited for forming such interconnects in microelectronics fabrications of the sub 0.15 micron generation.

Abstract: A method of fabricating trenches has been achieved. The method may be applied to damascene and dual damascene contacts to prevent damage to organic low dielectric constant materials due to photoresist ashing. A semiconductor substrate is provided. A first dielectric layer is deposited overlying the semiconductor substrate. A first etch stopping layer is deposited overlying the first dielectric layer. A second etch stopping layer is deposited overlying the first etch stopping layer. An optional anti-reflective coating is applied. A photoresist layer is deposited. The photoresist layer is patterned to define openings for planned trenches. The second etch stopping layer is etched through to form a hard mask for the planned trenches. The photoresist layer is stripped away by ashing where the first etch stopping layer protects the first dielectric layer from damage due to the presence of oxygen radicals.

Abstract: A method for forming dual-damascene type conducting interconnects with non-metallic barriers that protect said interconnects from fluorine out-diffusion from surrounding low-k, fluorinated dielectric materials. One embodiment of the method is particularly suited for forming such interconnects in microelectronics fabrications of the sub 0.15 micron generation.

Abstract: A method for reducing copper diffusion into an inorganic dielectric layer adjacent to a copper structure by doping the inorganic dielectric layer with a reducing agent (e.g. phosphorous, sulfur, or both) during plasma enhanced chemical vapor deposition. The resulting doped inorganic dielectric layer can reduce copper diffusion without a barrier layer reducing fabrication cost and cycle time, as well as reducing RC delay.

Abstract: A method for forming an extended metal gate without poly wrap around effects. A semiconductor structure is provided having a gate structure thereon. The gate structure comprising a gate dielectric layer, a gate silicon layer, a doped silicon oxide layer, and a disposable gate layer stacked sequentially. Spacers are formed on the sidewalls of the gate structure. A dielectric gapfill layer is formed over the semiconductor structure and the gate structure and planarized, stopping on the disposable gate layer. A first silicon nitride layer is formed over the disposable gate layer, and a dielectric layer is formed over the first silicon nitride layer. The dielectric layer is patterned to form a trench over the gate structure; wherein the trench has a width greater than the width of the gate structure. The first silicon nitride layer in the bottom of the trench and the disposable gate layer are removed using one or more selective etching processes.

Abstract: A new method of depositing a copper layer, using disproportionation of Cu(I) ions from a solution stabilized by a polar organic solvent, for single and dual damascene interconnects in the manufacture of an integrated circuit device has been achieved. A dielectric layer, which may comprise a stack of dielectric material, is provided overlying a semiconductor substrate. The dielectric layer is patterned to form vias and trenches for planned dual damascene interconnects. A barrier layer is deposited overlying the dielectric layer to line the vias and trenches. A simple Cu(I) ion solution, stabilized by a polar organic solvent, is coated overlying said barrier layer. Water is added to the stabilized simple Cu(I) ion solution to cause disproportionation of the simple Cu(I) ion from the Cu(I) ion solution. A copper layer is deposited overlying the barrier layer.

Abstract: A method for reducing RC delay by forming an air gap between conductive lines. A sacrificial layer is formed over a semiconductor structure, filling the gaps between conductive lines on the semiconductor structure. An air bridge layer is formed over the sacrificial layer. The semiconductor structure is exposed to an oxygen plasma, which penetrates through pores in the air bridge layer to react with the sacrificial layer, whereby the sacrificial layer is removed through the air bridge layer. The sacrificial layer and/or the air bridge layer comprise buckminsterfullerene. The air bridge layer can comprise buckminsterfullerene incorporated in an inorganic spin-on material. The buckminsterfullerene reacts with the oxygen plasma and is removed to form a porous air bridge layer. Then the oxygen species from the plasma penetrate the porous air bridge layer to react with and remove the sacrificial layer.

Abstract: A method for forming dual-damascene type conducting interconnects with non-metallic barriers that protect said interconnects from fluorine out-diffusion from surrounding low-k, fluorinated dielectric materials. One embodiment of the method is particularly suited for forming such interconnects in microelectronics fabrications of the sub 0.15 micron generation.

Abstract: A method to fabricate a floating gate with a sloping sidewall for a Flash Memory is described. Field oxide isolation regions are provided in the substrate. A silicon oxide layer is provided overlying the isolation regions and the substrate. A first polysilicon layer is deposited overlying the silicon oxide layer. A photoresist layer is deposited overlying the first polysilicon layer. The photoresist layer is etched to remove sections of the photoresist as defined by photolithographic process. The photoresist layer, the first polysilicon layer, and the silicon oxide layer are etched in areas uncovered by the photoresist layer to create structures with sloping sidewall edges. The photoresist layer is etched away. An interpoly dielectric layer is deposited overlying the structures, the sloping sidewall edges, and the isolation regions. A second polysilicon layer is deposited overlying the interpoly dielectric and the fabrication of the integrated circuit device is completed.

Abstract: A process for forming a groove in a semiconductor substrate, to be used to fabricate grooved gate, MOSFET devices, has been developed. The process features the use of an insulator mask, used as an etch mask for definition of the groove feature in the semiconductor substrate. A selective, anisotropic RIE procedure, using an etchant with a specific etch rate ratio of silicon, (semiconductor substrate), to silicon oxide, (insulator mask), is used to establish the desired groove depth, in the semiconductor substrate. The combination of a specific thickness of insulator shape, and a specific etch rate ratio for the selective, anisotropic RIE procedure, allows the desired depth of the groove to be established when the insulator shape is completely removed from the top surface of the semiconductor substrate.

Abstract: In accordance with the objects of this invention a new method to prevent copper contamination of the intermetal dielectric layer during etching, CMP, or post-etching and post-CMP cleaning by forming a dielectric cap for isolation of the underlying dielectric layer is described. In one embodiment of the invention, a dielectric layer is provided overlying a semiconductor substrate. A dielectric cap layer is deposited overlying the dielectric layer. A via is patterned and filled with a metal layer and planarized. A copper layer is deposited overlying the planarized metal layer and dielectric cap layer. The copper layer is etched to form a copper line wherein the dielectric cap layer prevents copper contamination of the dielectric layer during etching and cleaning. In another embodiment of the invention, a dielectric layer is provided overlying a semiconductor substrate. A dielectric cap layer is deposited overlying the dielectric layer.

Abstract: An improved method for removing a photoresist mask from an etched aluminum pattern after etching the pattern in a chlorine containing plasma has been developed. The method is a five step process, in which the first step is in a microwave generated plasma containing O2 and H2O; the second step is in a microwave generated plasma containing O2 and N2; the third step is in a microwave generated plasma containing H2O; the fourth step is in a microwave generated plasma containing O2 and N2; and the fifth step is in a microwave generated plasma containing H2O. The first step which initiates removal of photoresist while simultaneously beginning the passivation process causes residue-free removal of photoresist following etching of aluminum or aluminum-copper layers in chlorine bearing etchants.

Abstract: A method for reducing RC delay in integrated circuits by lowering the dielectric constant of the intermetal dielectric material between metal interconnects or metal damascene interconnects is described. The dielectric constant of the intermetal dielectric is lowered by introducing air into the intermetal dielectric between metal interconnections. An air bridge comprising a porous material, preferably amorphous silicon, porous silicon oxide, or porous silsesquioxane, is deposited over a layer containing a reactive organic material. An oxygen plasma treatment or an anisotropic etching through the pores in the air bridge layer removes at least a portion of the reactive material, leaving air plugs within the intermetal dielectric.

Abstract: A new method of depositing a copper layer, using disproportionation of Cu(I) ions from a solution stabilized by a polar organic solvent, for single and dual damascene interconnects in the manufacture of an integrated circuit device has been achieved. A dielectric layer, which may comprise a stack of dielectric material, is provided overlying a semiconductor substrate. The dielectric layer is patterned to form vias and trenches for planned dual damascene interconnects. A barrier layer is deposited overlying the dielectric layer to line the vias and trenches. A simple Cu(I) ion solution, stabilized by a polar organic solvent, is coated overlying said barrier layer. Water is added to the stabilized simple Cu(I) ion solution to cause disproportionation of the simple Cu(I) ion from the Cu(I) ion solution. A copper layer is deposited overlying the barrier layer.

Abstract: A method for introducing air into the gaps between neighboring conducting structures in a microelectronics fabrication in order to reduce the capacitative coupling between them. A patterned metal layer is deposited on a substrate. The layer is lined with a CVD-oxide. A disposable gap-filling material is deposited over the lined metal layer. A two layer “air-bridge” is formed over the gap-fill by depositing a layer of TiN over a layer of CVD-oxide. This structure is rendered porous by several chemical processes. An oxygen plasma is passed through the porous air-bridge to react with and dissolve the gap-fill beneath it. The reaction products escape through the porous air-bridge resulting in air-filled gaps.

Abstract: An effective copper decontamination method in the fabrication of integrated circuits is achieved. An organic-based HFACAC decontamination compound in vapor phase is sprayed over elemental copper found on equipment or tools or as a spill wherein the compound reacts with all of the elemental copper and forms a volatile compound that can be flushed away thereby completing copper decontamination.

Abstract: A method of cleaning elemental copper, cobalt, or nickel from the surface of equipment hardware without corroding or damaging the equipment parts and surfaces in the event of wafer breakage and non-wafer breakage is described. A solution comprising an alkyldione peroxide, a stabilizing agent, and alcohols is used to oxidize the metal and form soluble complexes which are removed by the cleaning solution. Also, a novel alkyldione peroxide solution for cleaning elemental copper, cobalt, or nickel from the surface of equipment hardware in the event of wafer breakage and non-wafer breakage is provided.