Abstract: Patterned copper structures are fabricated by selectively capping the copper employing selective etching and/or selective electroplating in the presence of a liner material. Apparatus for addressing the problem of an increased resistive path as electrolyte during electroetching and/or electroplating flows from the wafer edge inwards is provided.

Abstract: A semiconductor micro-electromechanical system (MEMS) switch provided with noble metal contacts that act as an oxygen barrier to copper electrodes is described. The MEMS switch is fully integrated into a CMOS semiconductor fabrication line. The integration techniques, materials and processes are fully compatible with copper chip metallization processes and are typically, a low cost and a low temperature process (below 400° C.). The MEMS switch includes: a movable beam within a cavity, the movable beam being anchored to a wall of the cavity at one or both ends of the beam; a first electrode embedded in the movable beam; and a second electrode embedded in an wall of the cavity and facing the first electrode, wherein the first and second electrodes are respectively capped by the noble metal contact.

Abstract: Methods and compositions for electro-chemical-mechanical polishing (e-CMP) of silicon chip interconnect materials, such as copper, are provided. The methods include the use of compositions according to the invention in combination with pads having various configurations.

Abstract: A method to electrolessly plate a CoWP alloy on copper in a reproducible manner that is effective for a manufacturable process. In the method, a seed layer of palladium (Pd) is deposited on the copper by an aqueous seeding solution of palladium acetate, acetic acid and chloride. Thereafter, a complexing solution is applied to remove any Pd ions which are adsorbed on surfaces other than the copper. Finally, a plating solution of cobalt (Co), tungsten (W) and phosphorous (P) is applied to the copper so as to deposit a layer of CoWP on the Pd seed and copper.

Abstract: An integrated circuit structure is disclosed that has a layer of logical and functional devices and an interconnection layer above the layer of logical and functional devices. The interconnection layer has a substrate, conductive features within the substrate and caps positioned only above the conductive features.

Abstract: A structure incorporates very low dielectric constant (k) insulators with copper wiring to achieve high performance interconnects. The wiring is supported by a relatively durable low k dielectric such as SiLk or SiO2 and a very low k and less-robust gap fill dielectric is disposed in the remainder of the structure, so that the structure combines a durable layer for strength with a very low k dielectric for interconnect electrical performance.

Abstract: Patterned copper structures are fabricated by selectively capping the copper employing selective etching and/or selective electroplating in the presence of a liner material. Apparatus for addressing the problem of an increased resistive path as electrolyte during electroetching and/or electroplating flows from the wafer edge inwards is provided.

Abstract: Defects on the edge of copper interconnects for back end of the line semiconductor devices are alleviated by an interconnect that comprises an impure copper seed layer. The impure copper seed layer covers a barrier layer, which covers an insulating layer that has an opening. Electroplated copper fills the opening in the insulating layer. Through a chemical mechanical polish, the barrier layer, the impure an impure copper seed layer derived from an electroplated copper bath copper seed layer, and the electroplated copper are planarized to the insulating layer.

Abstract: A structure incorporates very low dielectric constant (k) insulators with copper wiring to achieve high performance interconnects. The wiring is supported by a relatively durable low k dielectric such as SiLk or SiO2 and a very low k and less robust gap fill dielectric is disposed in the remainder of the structure, so that the structure combines a durable layer for strength with a very low k dielectric for interconnect electrical performance.

Abstract: The present invention provides a method for forming a self-aligned Ni alloy silicide contact. The method of the present invention begins by first depositing a conductive Ni alloy with Pt and optionally at least one of the following metals Pd, Rh, Ti, V, Cr, Zr, Nb, Mo, Hf, Ta, W or Re over an entire semiconductor structure which includes at least one gate stack region. An oxygen diffusion barrier comprising, for example, Ti, TiN or W is deposited over the structure to prevent oxidation of the metals. An annealing step is then employed to cause formation of a NiSi, PtSi contact in regions in which the metals are in contact with silicon. The metal that is in direct contact with insulating material such as SiO2 and Si3N4 is not converted into a metal alloy silicide contact during the annealing step. A selective etching step is then performed to remove unreacted metal from the sidewalls of the spacers and trench isolation regions.

Abstract: Patterned copper structures are fabricated by selectively capping the copper employing selective etching and/or selective electroplating in the presence of a liner material. Apparatus for addressing the problem of an increased resistive path as electrolyte during electroetching and/or electroplating flows from the wafer edge inwards is provided.

Abstract: An integrated circuit structure is disclosed that has a layer of logical and functional devices and an interconnection layer above the layer of logical and functional devices. The interconnection layer has a substrate, conductive features within the substrate and caps positioned only above the conductive features.

Abstract: A structure incorporates very low dielectric constant (k) insulators with copper wiring to achieve high performance interconnects. The wiring is supported by a relatively durable low k dielectric such as SiLk or SiO2 and a very low k and less-robust gap fill dielectric is disposed in the remainder of the structure, so that the structure combines a durable layer for strength with a very low k dielectric for interconnect electrical performance.

Abstract: An integrated circuit structure is disclosed that has a layer of logical and functional devices and an interconnection layer above the layer of logical and functional devices. The interconnection layer has a substrate, conductive features within the substrate and caps positioned only above the conductive features.

Abstract: A semiconductor micro-electromechanical system (MEMS) switch provided with noble metal contacts that act as an oxygen barrier to copper electrodes is described. The MEMS switch is fully integrated into a CMOS semiconductor fabrication line. The integration techniques, materials and processes are fully compatible with copper chip metallization processes and are typically, a low cost and a low temperature process (below 400°0 C.). The MEMS switch includes: a movable beam within a cavity, the movable beam being anchored to a wall of the cavity at one or both ends of the beam; a first electrode embedded in the movable beam; and a second electrode embedded in an wall of the cavity and facing the first electrode, wherein the first and second electrodes are respectively capped by the noble metal contact.

Abstract: Patterned copper structures are fabricated by selectively capping the copper employing selective etching and/or selective electroplating in the presence of a liner material. Apparatus for addressing the problem of an increased resistive path as electrolyte during electroetching and/or electroplating flows from the wafer edge inwards is provided.

Abstract: A method is described for fabricating an encapsulated metal structure in a feature formed in a substrate. The sidewalls and bottom of the feature are covered by a barrier layer and the feature is filled with metal, preferably by electroplating. A recess is formed in the metal, and an additional barrier layer is deposited, covering the top surface of the metal and contacting the first barrier layer. The additional barrier layer is planarized, preferably by chemical-mechanical polishing. The method may be used in fabricating a MIM capacitor, with the encapsulated metal structure serving as the lower plate of the capacitor. A second substrate layer is deposited on the top surface of the substrate, with an opening overlying the encapsulated metal structure. A dielectric layer is deposited in the opening, covering the encapsulated metal structure at the bottom thereof. An additional layer, serving as the upper plate of the capacitor, is deposited to cover the dielectric layer and to fill the opening.

Abstract: Slurry compositions comprising an oxidizing agent, optionally a copper corrosion inhibitor, abrasive particles; surface active agent, a service of chloride and a source of sulfate ions.

Abstract: A method is described for fabricating an encapsulated metal structure in a feature formed in a substrate. The sidewalls and bottom of the feature are covered by a barrier layer and the feature is filled with metal, preferably by electroplating. A recess is formed in the metal, and an additional barrier layer is deposited, covering the top surface of the metal and contacting the first barrier layer. The additional barrier layer is planarized, preferably by chemical-mechanical polishing. The method may be used in fabricating a MIM capacitor, with the encapsulated metal structure serving as the lower plate of the capacitor. A second substrate layer is deposited on the top surface of the substrate, with an opening overlying the encapsulated metal structure. A dielectric layer is deposited in the opening, covering the encapsulated metal structure at the bottom thereof. An additional layer, serving as the upper plate of the capacitor, is deposited to cover the dielectric layer and to fill the opening.

Abstract: A method is described for fabricating an encapsulated metal structure in a feature formed in a substrate. The sidewalls and bottom of the feature are covered by a barrier layer and the feature is filled with metal, preferably by electroplating. A recess is formed in the metal, and an additional barrier layer is deposited, covering the top surface of the metal and contacting the first barrier layer. The additional barrier layer is planarized, preferably by chemical-mechanical polishing. The method may be used in fabricating a MIM capacitor, with the encapsulated metal structure serving as the lower plate of the capacitor. A second substrate layer is deposited on the top surface of the substrate, with an opening overlying the encapsulated metal structure. A dielectric layer is deposited in the opening, covering the encapsulated metal structure at the bottom thereof. An additional layer, serving as the upper plate of the capacitor, is deposited to cover the dielectric layer and to fill the opening.