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: Methods for forming dual-metal gate CMOS transistors are described. An NMOS and a PMOS active area of a semiconductor substrate are separated by isolation regions. A metal layer is deposited over a gate dielectric layer in each active area. Oxygen ions are implanted into the metal layer in one active area to form an implanted metal layer which is oxidized to form a metal oxide layer. Thereafter, the metal layer and the metal oxide layer are patterned to form a metal gate in one active area and a metal oxide gate in the other active area wherein the active area having the gate with the higher work function is the PMOS active area. Alternatively, both gates may be metal oxide gates wherein the oxide concentrations of the two gates differ. Alternatively, a dummy gate may be formed in each of the active areas and covered with a dielectric layer. The dielectric layer is planarized thereby exposing the dummy gates. The dummy gates are removed leaving gate openings to the semiconductor substrate.

Abstract: A new method of forming a sharp tip on a floating gate in the fabrication of a EEPROM memory cell is described. A first gate dielectric layer is provided on a substrate. A second gate dielectric layer is deposited overlying the first gate dielectric layer. A floating gate/control gate stack is formed overlying the second gate dielectric layer. One sidewall portion of the floating gate is covered with a mask. The second gate dielectric layer not covered by the mask is etched away whereby an undercut of the floating gate is formed in the second gate dielectric layer. The mask is removed. Polysilicon spacers are formed on sidewalls of the floating gate wherein one of the polysilicon spacers fills the undercut thereby forming a sharp polysilicon tip to improve the erase efficiency of the memory cell.

Abstract: A new method and apparatus is provided that can be applied to clean outer edges of semiconductor substrates. Under the first embodiment of the invention, a brush is mounted on the surface of the substrate around the periphery of the substrate, chemicals are fed to the surface that is being cleaned by means of a hollow core on which the cleaning brush is mounted. The surface that is being cleaned rotates at a relatively high speed thereby causing the chemicals that are deposited on this surface (by the brush) to remain in the edge of the surface. Under the second embodiment of the invention, a porous roller is mounted between a chemical reservoir and the surface that is being cleaned, the surface that is being cleaned rotates at a relatively high speed. The chemicals that are deposited by the interfacing porous roller onto the surface that is being cleaned therefore remain at the edge of this surface thereby causing optimum cleaning action of the edge of the surface.

Abstract: A method for making low sheet resistance local metal interconnections and improved transistor performance is described. The method involves patterning a polysilicon layer and a silicon nitride (Si3N4) cap layer over device areas to form FET gate electrodes, and the patterned polysilicon extends over the field oxide regions to form portions of the local interconnections. After forming source/drain areas and sidewall spacers on the FET gate electrodes, a silicon oxide (SiO2) insulating layer is deposited and polished back to the Si3N4 cap. The Si3N4 is then selectively removed over the patterned polysilicon layer, leaving recesses in the SiO2 layer. After etching contact openings in the SiO2 layer to the substrate, a high electrically conducting metal layer, having a barrier layer, is deposited and patterned to complete the local interconnections.

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 completely removing dielectric layers formed selectively upon a substrate employed within a microelectronics fabrication from regions wherein closely spaced structures such as self-aligned metal silicide (or salicide) electrical contacts may be fabricated, with improved properties and with attenuated degradation. There is first provided a substrate with employed within a microelectronics fabrication having formed thereon patterned microelectronics layers with closely spaced features. There is then formed a salicide block layer employing silicon oxide dielectric material which may be selectively doped. There is then formed over the substrate a patterned photoresist etch mask layer. There is then etched the pattern of the patterned photoresist etch mask layer employing dry plasma reactive ion etching. An anhydrous etching environment is then employed to completely remove the silicon oxide dielectric salicide block layer with attenuated degradation of the microelectronics fabrication.

Abstract: A method etching an organic-based, low dielectric constant material in the manufacture of an integrated circuit device has been achieved. Organic materials without silicon and organic materials without fluorine can be etched by using, for example, hydrazine or ammonia gas. Organic materials with silicon can also be etched with the addition of a fluorine-containing or chlorine-containing gas. A semiconductor substrate is provided. A low dielectric constant organic-based material is deposited overlying the semiconductor substrate. The low dielectric constant organic-based material is etched to form desirable features using a plasma containing a gas comprising a nitrogen and hydrogen containing molecule, and the integrated circuit device is completed.

Abstract: A process for forming a first group of gate structures, designed to operate at a lower voltage than a simultaneously formed second group of gate structures, has been developed. The process features the thermal growth of a first silicon dioxide gate insulator layer, on a portion of the semiconductor substrate used for the lower voltage gate structures, while simultaneously forming a thicker, second silicon dioxide gate insulator layer on a portion of the semiconductor substrate used for the higher voltage gate structures. The thermal growth of the first, and second silicon dioxide gate insulator layers is accomplished via diffusion of the oxidizing species: through a thick, composite silicon nitride layer, to obtain the thinner, first silicon dioxide gate insulator layer, on a first portion of the semiconductor substrate; and through a thinner, silicon nitride layer, to obtain the thicker, second silicon dioxide gate insulator layer, on a second portion of the semiconductor substrate.

Abstract: A method for forming a patterned microelectronic layer. There is first provided a substrate. There is then formed over the substrate a multi-layer stack layer comprising: (1) a first lower microelectronic layer; (2) a second intermediate patterned microelectronic layer formed over the first lower microelectronic layer; and (3) a third upper patterned microelectronic layer formed over the second intermediate patterned microelectronic layer, where the first lower microelectronic layer and the third upper patterned microelectronic layer are susceptible to etching within a first etchant. There is then formed encapsulating the first lower microelectronic layer and at least portion of the second intermediate patterned microelectronic layer while leaving exposed at least a portion of the third upper patterned microelectronic layer an encapsulating 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 new method of forming a metal oxide high dielectric constant layer in the manufacture of an integrated circuit device has been achieved. A substrate is provided. A metal oxide layer is deposited overlying the substrate by reacting a precursor with an oxidant gas in a chemical vapor deposition chamber. The metal oxide layer may comprise hafnium oxide or zirconium oxide. The precursor may comprise metal alkoxide, metal alkoxide containing halogen, metal &bgr;-diketonate, metal fluorinated &bgr;-diketonate, metal oxoacid, metal acetate, or metal alkene. The metal oxide layer is annealed to cause densification and to complete the formation of the metal oxide dielectric layer in the manufacture of the integrated circuit device. A composite metal oxide-silicon oxide (MO2-SiO2) high dielectric constant layer may be deposited using a precursor comprising metal tetrasiloxane.

Abstract: A method to remove a metal from over a substrate in the fabrication of an integrated circuit device. The invention comprises providing a metal layer over a substrate. The metal layer is exposed to a reactant gas to form at least a solid metal containing product. The reactant gas preferably contains sulfur and oxygen. The reactant gas more preferably comprises sulfur dioxide or sulfur trioxide. The reactant gas is preferably heated and optionally exposed to a plasma. Next, the metal containing product is removed using a liquid, thereby removing at least portion of the metal layer from over the substrate.

Abstract: A method of forming interconnect structures in a semiconductor device, comprising the following steps. A semiconductor structure is provided. In the first embodiment, at least one metal line is formed over the semiconductor structure. A silicon-rich carbide barrier layer is formed over the metal line and semiconductor structure. Finally, a dielectric layer, that may be fluorinated, is formed over the silicon-rich carbide layer. In the second embodiment, at least one fluorinated dielectric layer, that may be fluorinated, is formed over the semiconductor structure. The dielectric layer is patterned to form an opening therein. A silicon-rich carbide barrier layer is formed within the opening. A metallization layer is deposited over the structure, filling the silicon-rich carbide barrier layer lined opening. Finally, the metallization layer may be planarized to form a planarized metal structure within the silicon-rich carbide barrier layer lined opening.

Abstract: Methods for forming dual-metal gate CMOS transistors are described. An NMOS and a PMOS active area of a semiconductor substrate are separated by isolation regions. A metal layer is deposited over a gate dielectric layer in each active area. Silicon ions are implanted into the metal layer in one active area to form an implanted metal layer which is silicided to form a metal silicide layer. Thereafter, the metal layer and the metal silicide layer are patterned to form a metal gate in one active area and a metal silicide gate in the other active area wherein the active area having the gate with the higher work function is the PMOS active area. Alternatively, both gates may be metal silicide gates wherein the silicon concentrations of the two gates differ. Alternatively, a dummy gate may be formed in each of the active areas and covered with a dielectric layer. The dielectric layer is planarized thereby exposing the dummy gates. The dummy gates are removed leaving gate openings to the semiconductor substrate.

Abstract: A new method of forming a dual damascene interconnect structure, wherein damage of interconnect and contamination of dielectrics during etching is minimized by having an embedded organic stop layer over the lower interconnect and later etching the organic stop layer with an H2 containing plasma, or hydrogen radical.

Abstract: An endpoint detection system for copper stripping using a colorimetric analysis of the change in concentration of a component is described, Wet copper stripping chemicals are used to strip copper from a wafer whereby an eluent is produced. The eluent is continuously analyzed by colorimetric analysis for the presence of copper. The copper stripping process is stopped when the presence of copper is no longer detected. Also novel compounds or chemicals for use in an endpoint detection system for copper stripping using a colorimetric analysis of the change in concentration of the novel compounds or chemicals are described. A composition of matter that serves as an indicator of the presence of copper by colorimetric analysis comprises: 1) Fast Sulphon Black F indicator and an ammonium ion-containing solution or 2) a complexing agent, comprising a diamine, an amine macrocycle, or a monoamine.

Abstract: A method of fabricating a dual gate electrode CMOS device having dual gate electrodes. An N+ poly gate is used for the nMOSFET and a metal gate is used for the pMOSFET. The N+ nMOSFET poly gate may be capped with a highly conductive metal to reduce its gate resistance. A sacrificial cap is used for the N+ poly gate to eliminate a mask level for the dual gate electrodes.

Abstract: A method of forming amorphous silicon spacers followed by the forming of metal nitride over the spacers in a copper damascene structure—single, dual, or multi-structure—is disclosed in order to prevent the formation of fluorides in copper. In a first embodiment, the interconnection between the copper damascene and an underlying copper metal layer is made by forming an opening from the dual damascene structure to the underlying copper layer after the formation of the metal nitride layer over the amorphous silicon spacers formed on the inside walls of the dual damascene structure. In the second embodiment, the interconnection between the dual damascene structure and the underlying copper line is made from the dual damascene structure by etching into the underlying copper layer after the forming of the amorphous silicon spacers and before the forming of the metal nitride layer.

Abstract: A new method of forming dual damascene interconnects has been achieved. A semiconductor substrate is provided. A dielectric layer is provided overlying the semiconductor substrate. A first photoresist layer is deposited overlying the dielectric layer. The first photoresist layer is exposed, but not developed, to define patterns where via trenches are planned. A second photoresist layer is deposited overlying the first photoresist layer. The second photoresist layer is exposed to define patterns where interconnect trenches are planned. The second photoresist layer and the first photoresist layer are developed to complete the via trench pattern of the first photoresist layer and the interconnect trench pattern of the second photoresist layer. The dielectric layer is etched through where defined by the via trench pattern of the first photoresist layer.