Abstract: Adhesion between a copper metallization layer and a dielectric barrier film may be promoted by stabilizing a flow of a silicon-containing precursor in a divert line leading to the chamber exhaust. The stabilized gas flow is then introduced to the processing chamber to precisely form a silicide layer over the copper. This silicidation step creates a network of strong Cu—Si bonds that prevent delamination of the barrier layer, while not substantially altering the sheet resistance and other electrical properties of the resulting metallization structure.

Abstract: Embodiments in accordance with the present invention relate to a number of techniques, which may be applied alone or in combination, to reduce charge damage of substrates exposed to electron beam radiation. In one embodiment, charge damage is reduced by establishing a robust electrical connection between the exposed substrate and ground. In another embodiment, charge damage is reduced by modifying the sequence of steps for activating and deactivating the electron beam source to reduce the accumulation of charge on the substrate. In still another embodiment, a plasma is struck in the chamber containing the e-beam treated substrate, thereby removing accumulated charge from the substrate. In a further embodiment of the present invention, the voltage of the anode of the e-beam source is reduced in magnitude to account for differences in electron conversion efficiency exhibited by different cathode materials.

Abstract: A system, method and medium of detecting a transition interface between a first dielectric material and an adjacent second dielectric material in a semiconductor wafer during a chemical-mechanical polishing process includes impinging an incident light of a predetermined wavelength on the semiconductor wafer at a first time, detecting at least one first intensity of at least one first reflected light, impinging the incident light of the predetermined wavelength on the semiconductor wafer at a second time, detecting at least one second intensity of at least one second reflected light, and determining a difference between the at least one first intensity and the at least one second intensity. If the difference between the at least one first intensity and the at least one second intensity is above a predetermined threshold, the chemical-mechanical polishing process is terminated.

Abstract: The invention provides a removable first edge ring configured for pin and recess/slot coupling with a second edge ring disposed on the substrate support. In one embodiment, a first edge ring includes a plurality of pins, and a second edge ring includes one or more alignment recesses and one or more alignment slots for mating engagement with the pins. Each of the alignment recesses and alignment slots are at least as wide as the corresponding pins, and each of the alignment slots extends in the radial direction a length that is sufficient to compensate for the difference in thermal expansion between the first edge ring and the second edge ring.

Abstract: Pregabalin substantially in an amorphous form is disclosed. A composition comprising amorphous pregabalin in a solid form, wherein at least about 80% by weight of the solid is amorphous pregabalin in an amorphous form is also disclosed. The present invention also provides a process for preparing amorphous pregabalin substantially in an amorphous form by providing a solution of amorphous pregabalin in one or more solvents capable of dissolving the pregabalin and substantially removing the solvent from the solution.

Abstract: A multi-step sputtering process in plasma sputter reactor having target and magnetron operable in two modes, for example, in a substrate sputter etch and a substrate sputter deposition. The target has an annular vault facing the wafer to be sputter coated. Various types of magnetic means positioned around the vault create a magnetic field supporting a plasma extending over a large volume of the vault. An integrated copper via filling process with the inventive reactor or other reactor includes a first step of highly ionized sputter deposition of copper, which can optionally be used to remove the barrier layer at the bottom of the via, a second step of more neutral, lower-energy sputter deposition of copper to complete the seed layer, and a third step of electroplating copper into the hole to complete the metallization. The first two steps can be also used with barrier metals.

Abstract: A method and system of processing a semiconductor substrate includes, in one or more embodiments, depositing a protective layer on the substrate surface comprising a conductive element disposed in a dielectric material; processing the protective layer to expose the conductive element; electrolessly depositing a metallic passivating layer onto the conductive element; and removing at least a portion of the protective layer from the substrate after electroless deposition. In another aspect, a method and system of processing a semiconductor includes depositing a metallic passivating layer onto a substrate surface comprising a conductive element, masking the passivating layer to protect the underlying conductive element of the substrate surface, removing the unmasked passivating layer, and removing the mask from the passivating layer.

Abstract: The present invention provides methods for fabricating horizontal interconnect lines for use in semiconductor wafer fabrication. A dielectric layer is deposited on a dielectric stack having a planarized top surface. The dielectric layer is not planarized at this stage of the process. A pre-planarizing thickness profile of the non-planarized dielectric layer is determined and recorded. An interconnect line trench is then etched through the dielectric layer. A sandwich layer including a conductive Cu diffusion barrier layer and a Cu seed layer is deposited in the trench and on the dielectric layer. A Cu comprising metal is deposited in the sandwich lined trench. A Cu metal overburden is thereby deposited on the section of the sandwich layer that is positioned on the dielectric layer. A first CMP process is used to remove the Cu overburden and the Cu seed layer that is formed in the sandwich layer portion on the dielectric layer.

Abstract: The present invention provides techniques for fabricating integrated circuit structures in semiconductor wafer fabrication. A via hole is prepared in a dielectric stack having a bottom via etch stop layer. The via hole is not extended through the via etch stop layer at this stage of the process. The via hole is partly filled with a sacrificial via fill such that a recess without sacrificial via fill is formed in the top portion of the via hole. A substantially conformal sacrificial layer is deposited on the top surface of the dielectric stack and in the recess. Then, a photoresist layer is deposited on the sacrificial fill. A trench etch mask overlaying the via hole, is developed in the photoresist layer. This mask is etched through the sacrificial layer that is formed on the top surface of the dielectric stack as well as through the sacrificial fill and sacrificial layer that is present in the via hole.

Abstract: Methods are provided for depositing a dielectric material for use as an anti-reflective coating and sacrificial dielectric material in damascene formation. In one aspect, a process is provided for processing a substrate including depositing an acidic dielectric layer on the substrate by reacting an oxygen-containing organosilicon compound and an acidic compound, depositing a photoresist material on the acidic dielectric layer, and patterning the photoresist layer. The acidic dielectric layer may be used as a sacrificial layer in forming a feature definition by etching a partial feature definition, depositing the acidic dielectric material, etching the remainder of the feature definition, and then removing the acidic dielectric material to form a feature definition.

Abstract: Embodiments in accordance with the present invention relate to a number of techniques, which may be applied alone or in combination, to reduce charge damage of substrates exposed to electron beam radiation. In one embodiment, charge damage is reduced by establishing a robust electrical connection between the exposed substrate and ground. In another embodiment, charge damage is reduced by modifying the sequence of steps for activating and deactivating the electron beam source to reduce the accumulation of charge on the substrate. In still another embodiment, a plasma is struck in the chamber containing the e-beam treated substrate, thereby removing accumulated charge from the substrate. In a further embodiment of the present invention, the voltage of the anode of the e-beam source is reduced in magnitude to account for differences in electron conversion efficiency exhibited by different cathode materials.

Abstract: A system, method and medium of detecting a transition interface between a first dielectric material and an adjacent second dielectric material in a semiconductor wafer during a chemical-mechanical polishing process includes impinging an incident light of a predetermined wavelength on the semiconductor wafer at a first time, detecting at least one first intensity of at least one first reflected light, impinging the incident light of the predetermined wavelength on the semiconductor wafer at a second time, detecting at least one second intensity of at least one second reflected light, and determining a difference between the at least one first intensity and the at least one second intensity. If the difference between the at least one first intensity and the at least one second intensity is above a predetermined threshold, the chemical-mechanical polishing process is terminated.

Abstract: A method of depositing a low dielectric constant film on a substrate and post-treating the low dielectric constant film is provided. The post-treatment includes rapidly heating the low dielectric constant film to a desired high temperature and then rapidly cooling the low dielectric constant film such that the low dielectric constant film is exposed to the desired high temperature for about five seconds or less. In one aspect, the post-treatment also includes exposing the low dielectric constant film to an electron beam treatment and/or UV radiation.

Abstract: A multi-step sputtering process in plasma sputter reactor having target and magnetron operable in two modes, for example, in a substrate sputter etch and a substrate sputter deposition. The target has an annular vault facing the wafer to be sputter coated. Various types of magnetic means positioned around the vault create a magnetic field supporting a plasma extending over a large volume of the vault. An integrated copper via filling process with the inventive reactor or other reactor includes a first step of highly ionized sputter deposition of copper, which can optionally be used to remove the barrier layer at the bottom of the via, a second step of more neutral, lower-energy sputter deposition of copper to complete the seed layer, and a third step of electroplating copper into the hole to complete the metallization. The first two steps can be also used with barrier metals.

Abstract: A multi-step sputtering process in plasma sputter reactor having target and magnetron operable in two modes, for example, in a substrate sputter etch and a substrate sputter deposition. The target has an annular vault facing the wafer to be sputter coated. Various types of magnetic means positioned around the vault create a magnetic field supporting a plasma extending over a large volume of the vault. An integrated copper via filling process with the inventive reactor or other reactor includes a first step of highly ionized sputter deposition of copper, which can optionally be used to remove the barrier layer at the bottom of the via, a second step of more neutral, lower-energy sputter deposition of copper to complete the seed layer, and a third step of electroplating copper into the hole to complete the metallization. The first two steps can be also used with barrier metals.

Abstract: A two-stage plasma enhance dielectric deposition with a first stage of low capacitively-coupled RF bias with conformal deposition (202) followed by high capacitively-coupled RF bias for planarizing deposition (204) limits the charge build up on the underlying structure (104, 106, 108).

Abstract: A method of depositing a low dielectric constant film on a substrate and post-treating the low dielectric constant film is provided. The post-treatment includes rapidly heating the low dielectric constant film to a desired high temperature and then rapidly cooling the low dielectric constant film such that the low dielectric constant film is exposed to the desired high temperature for about five seconds or less. In one aspect, the post-treatment also includes exposing the low dielectric constant film to an electron beam treatment and/or UV radiation.

Abstract: Embodiments in accordance with the present invention relate to a number of techniques, which may be applied alone or in combination, to reduce charge damage of substrates exposed to electron beam radiation. In one embodiment, charge damage is reduced by establishing a robust electrical connection between the exposed substrate and ground. In another embodiment, charge damage is reduced by modifying the sequence of steps for activating and deactivating the electron beam source to reduce the accumulation of charge on the substrate. In still another embodiment, a plasma is struck in the chamber containing the e-beam treated substrate, thereby removing accumulated charge from the substrate. In a further embodiment of the present invention, the voltage of the anode of the e-beam source is reduced in magnitude to account for differences in electron conversion efficiency exhibited by different cathode materials.

Abstract: Embodiments of the present invention generally relate to a method and apparatus for planarizing a substrate by electropolishing techniques. Certain embodiments of an electropolishing apparatus include a contact ring adapted to support a substrate, a cell body adapted to hold an electropolishing solution, a fluid supply system adapted to provide the electropolishing solution to the cell body, a cathode disposed within the cell body, a power supply system in electrical communication with the contact ring and the cathode, and a controller coupled to at least the fluid supply system and the power supply system. The controller may be adapted to provide a first set of electropolishing conditions to form a boundary layer between the substrate and the electropolishing solution to an initial thickness and may be adapted to provide a second set of electropolishing conditions to control the boundary layer to a subsequent thickness less than or equal to the initial thickness.

Abstract: Adhesion between a copper metallization layer and a dielectric barrier film may be promoted by stabilizing a flow of a silicon-containing precursor in a divert line leading to the chamber exhaust. The stabilized gas flow is then introduced to the processing chamber to precisely form a silicide layer over the copper. This silicidation step creates a network of strong Cu—Si bonds that prevent delamination of the barrier layer, while not substantially altering the sheet resistance and other electrical properties of the resulting metallization structure.