Abstract: A semiconductor interconnect structure having reduced hillock formation and a method for forming the same are provided. The semiconductor interconnect structure includes a conductor formed in a dielectric layer. The conductor includes at least three sub-layers, wherein the ratio of the impurity concentrations in neighboring sub-layers is preferably greater than about two.

Abstract: A conductive polymer between two metallic layers acts a glue layer, a barrier layer or an activation seed layer. The conductive polymer layer is employed to encapsulate a copper interconnection structure to prevent copper diffusion into any overlying layers and improve adhesive characteristics between the copper and any overlying layers.

Abstract: A method for forming a metal-insulator-metal capacitor in a multilevel semiconductor device utilizes the copper interconnect levels of the semiconductor device as parts of the capacitor. A lower capacitor plate consists of a copper interconnect level and a first metal layer formed on the copper interconnect level by selective deposition methods. The upper capacitor plate includes the same pattern as the capacitor dielectric, the pattern having an area less than the area of the lower capacitor plate. The upper capacitor plate is formed of a second metal layer. The first and second metal layers may each be formed of cobalt, tungsten, nickel, molybdenum, or a combinations of one of the aforementioned elements with boron and/or phosphorus. Conductive vias provide contact from the upper capacitor plate and lower capacitor plate, to interconnect levels.

Abstract: A semiconductor interconnect structure having reduced hillock formation and a method for forming the same are provided. The semiconductor interconnect structure includes a conductor formed in a dielectric layer. The conductor includes at least three sub-layers, wherein the ratio of the impurity concentrations in neighboring sub-layers is preferably greater than about two.

Abstract: A metal-insulator-metal capacitor formed in a multilevel semiconductor device utilizes the copper interconnect levels of the semiconductor device as parts of the capacitor. A lower capacitor plate consists of a copper interconnect level and a first metal layer formed on the copper interconnect level by selective deposition methods. The upper capacitor plate includes the same pattern as the capacitor dielectric, the pattern having an area less than the area of the lower capacitor plate. The upper capacitor plate is formed of a second metal layer. The first and second metal layers may each be formed of cobalt, tungsten, nickel, molybdenum, or a combinations of one of the aforementioned elements with boron and/or phosphorus. Conductive vias provide contact from the upper capacitor plate and lower capacitor plate, to interconnect levels.

Abstract: A method for fabricating an integrated circuit structure and the resulting integrated circuit structure are provided. The method includes forming a low-k dielectric layer; form an opening in the low-k dielectric layer; forming a barrier layer covering a bottom and sidewalls of the low-k dielectric layer; performing a treatment to the barrier layer in an environment comprising a treatment gas; and filling the opening with a conductive material, wherein the conductive material is on the barrier layer.

Abstract: A passivated metal structure and a method of forming the metal structure is disclosed. According to one embodiment, the patterned metal structure, such as conductive lines, are formed on a substrate. The copper lines are passivated by a polymer liner between the copper lines and a low k dielectric filling the spaces between the conductive lines. The polymer liner is preferably deposited on the sidewalls of the conductive lines by electro-grafting. The polymer liner may also be used in a damascene process according to a second embodiment.

Abstract: A semiconductor interconnect structure having reduced hillock formation and a method for forming the same are provided. The semiconductor interconnect structure includes a conductor formed in a dielectric layer. The conductor includes at least three sub-layers, wherein the ratio of the impurity concentrations in neighboring sub-layers is preferably greater than about two.

Abstract: The top surfaces of conductive features are treated with a treatment solution before forming a passivation layer over the conductive features. The treatment solution includes a cleaning solution and a chemical grafting precursor. The treatment solution may also include a leveling and wetting agent to improve coverage uniformity of the chemical grafting precursor. The method results in a uniform passivation layer formed over conductive features across a surface of a workpiece.

Abstract: A method for plating includes positioning a substrate facing a plating solution. The method also includes immersing the substrate into the plating solution while plating a layer of material over a surface of the substrate, wherein an immersion speed of the substrate is about 100 millimeters per second (mm/s) or more while at least one portion of the substrate contacts the plating solution.

Abstract: A method of forming a semiconductor device comprising: forming a gate dielectric layer over a channel region; forming a gate electrode on the gate dielectric layer; forming source/drain regions substantially aligned with respective edges of the gate electrode with the channel region therebetween; forming a thin metal layer on the source/drain regions; forming a metal alloy layer on the thin metal layer; and transforming the thin metal layer into a low resistance metal silicide.

Abstract: An apparatus includes an enclosure, at least one process chamber, a robot and at least one valve. The enclosure has a gas therein and at least one door configured to cover an opening into the enclosure. The gas includes at least one reduction gas. The robot is disposed within the enclosure and configured to transfer a substrate between the door and the process chamber. The valve is coupled to the enclosure.

Abstract: An integrated circuit includes a semiconductor substrate, a low-k dielectric layer over the semiconductor substrate, a first opening in the low-k dielectric layer, and a first diffusion barrier layer in the first opening covering the low-k dielectric layer in the first opening, wherein the first diffusion barrier layer has a bottom portion connected to sidewall portions, and wherein the sidewall portions have top surfaces close to a top surface of the low-k dielectric layer. The integrated circuit further includes a conductive line filling the first opening wherein the conductive line has a top surface lower than the top surfaces of the sidewall portions of the diffusion barrier layer, and a metal cap on the conductive line and only within a region directly over the conductive line.

Abstract: A method of forming an integrated circuit interconnect structure is presented. A first conductive line is formed over a semiconductor substrate. A conductive cap layer is formed on the first conductive line to improve device reliability. An etch stop layer (ESL) is formed on the conductive cap layer. An inter-level dielectric (IMD) is formed on the ESL. A via opening and a trench are formed in the ESL, IMD, and conductive cap layer. A recess is formed in the first conductive line. The recess can be formed by over etching when the first dielectric is etched, or by a separate process such as argon sputtering. A second conductive line is formed filling the trench, opening and recess.

Abstract: A semiconductor interconnect structure having reduced hillock formation and a method for forming the same are provided. The semiconductor interconnect structure includes a conductor formed in a dielectric layer. The conductor includes at least three sub-layers, wherein the ratio of the impurity concentrations in neighboring sub-layers is preferably greater than about two.

Abstract: A metal-insulator-metal capacitor formed in a multilevel semiconductor device utilizes the copper interconnect levels of the semiconductor device as parts of the capacitor. A lower capacitor plate consists of a copper interconnect level and a first metal layer formed on the copper interconnect level by selective deposition methods. The upper capacitor plate includes the same pattern as the capacitor dielectric, the pattern having an area less than the area of the lower capacitor plate. The upper capacitor plate is formed of a second metal layer. The first and second metal layers may each be formed of cobalt, tungsten, nickel, molybdenum, or a combinations of one of the aforementioned elements with boron and/or phosphorus. Conductive vias provide contact from the upper capacitor plate and lower capacitor plate, to interconnect levels.

Abstract: A conductive polymer between two metallic layers acts a glue layer, a barrier layer or an activation seed layer. The conductive polymer layer is employed to encapsulate a copper interconnection structure to prevent copper diffusion into any overlying layers and improve adhesive characteristics between the copper and any overlying layers.

Abstract: A method of forming a semiconductor device comprising: forming a gate dielectric layer over a channel region; forming a gate electrode on the gate dielectric layer; forming source/drain regions substantially aligned with respective edges of the gate electrode with the channel region therebetween; forming a thin metal layer on the source/drain regions; forming a metal alloy layer on the thin metal layer; and transforming the thin metal layer into a low resistance metal silicide.

Abstract: A passivated metal structure and a method of forming the metal structure is disclosed. According to one embodiment, the patterned metal structure, such as conductive lines, are formed on a substrate. The copper lines are passivated by a polymer liner between the copper lines and a low k dielectric filling the spaces between the conductive lines. The polymer liner is preferably deposited on the sidewalls of the conductive lines by electro-grafting. The polymer liner may also be used in a damascene process according to a second embodiment.

Abstract: The top surfaces of conductive features are treated with a treatment solution before forming a passivation layer over the conductive features. The treatment solution includes a cleaning solution and a chemical grafting precursor. The treatment solution may also include a leveling and wetting agent to improve coverage uniformity of the chemical grafting precursor. The method results in a uniform passivation layer formed over conductive features across a surface of a workpiece.