Abstract: Methods for processing substrate through a head that is configured to be placed in close non-contact proximity to a surface of a substrate are provided. One method includes applying a first fluid onto the surface of the substrate from conduits in the head when the head is in close proximity to the surface of the substrate and removing the first fluid from the surface of the substrate. The removing is processed just as first fluid is applied to the surface of the substrate, and the removing ensures that the applied first fluid is contained between a surface of the head and the surface of the substrate and the first fluid being applied and removed defines a controlled meniscus. The method further includes moving the controlled meniscus over different regions of the surface of the substrate when movement of the head or the substrate is dictated. The moving of the controlled meniscus enables processing of part or all of the surface of the substrate using the first fluid.

Abstract: One of many embodiments of a substrate preparation system is provided which includes a head having a head surface where the head surface is proximate to a surface of the substrate. The system also includes a first conduit for delivering a first fluid to the surface of the substrate through the head, and a second conduit for delivering a second fluid to the surface of the substrate through the head, where the second fluid is different than the first fluid. The system also includes a third conduit for removing each of the first fluid and the second fluid from the surface of the substrate where the first conduit, the second conduit and the third conduit act substantially simultaneously.

Abstract: Cleaning compounds, apparatus, and methods to remove contaminants from a substrate surface are provided. An exemplary cleaning compound to remove particulate contaminants from a semiconductor substrate surface is provided. The cleaning compound includes a viscous liquid with a viscosity between about 1 cP to about 10,000 cP. The cleaning compound also includes a plurality of solid components dispersed in the viscous liquid, the plurality of solid components interact with the particulate contaminants on the substrate surface to remove the particulate contaminants from the substrate surface.

Abstract: An apparatus for cleaning a semiconductor wafer edge is provided. The apparatus includes a film with an abrasive layer configured to contact the edge surface of a semiconductor substrate coated with a contaminant residue layer. A first reel having the film wound thereon and a second reel for receiving the film fed from the first reel are included. In one embodiment, a third reel configured to force the abrasive layer of the film against the edge surface of the semiconductor substrate so as to create an area of contact between the abrasive layer and the edge surface of the semiconductor substrate; and a pin that protrudes from to the top surface of the third reel. A system and method for cleaning a semiconductor wafer edge are also provided.

Abstract: A pressure is maintained within a volume within which a semiconductor wafer resides at a pressure that is sufficient to maintain a liquid state of a precursor fluid to a non-Newtonian fluid. The precursor fluid is disposed proximate to a material to be removed from the semiconductor wafer while maintaining the precursor fluid in the liquid state. The pressure is reduced in the volume within which the semiconductor wafer resides such that the precursor fluid disposed on the wafer within the volume is transformed into the non-Newtonian fluid. An expansion of the precursor fluid and movement of the precursor fluid relative to the wafer during transformation into the non-Newtonian fluid causes the resulting non-Newtonian fluid to remove the material from the semiconductor wafer.

Abstract: A first proximity head is configured to define a meniscus of a photoresist developer solution on a substrate. The meniscus is to be defined between a bottom of the first proximity head and the substrate. A second proximity head is configured to define a rinsing meniscus on the substrate and remove the rinsing meniscus from the substrate. The second proximity head is positioned to follow the first proximity head relative to a traversal direction of the first and second proximity heads over the substrate. Exposure of the substrate to the meniscus of photoresist developer solution causes previously irradiated photoresist material on the substrate to be developed to render a patterned photoresist layer. The first and second proximity heads enable precise control of a residence time of the photoresist developer solution on the substrate during the development process.

Abstract: In advanced electrolytic polish (AEP) method, a metal wafer (10) acts as an anodic electrodes and another metal plate (65) is used as a cathodic electrode. A voltage differential is applied to the anode and cathode under a predetermined anodic dissolution current density. This causes a reaction that provides a planarized surface on the metal wafers. Additives are included in the electrolyte solution (55) which adsorb onto the wafer surface urging a higher removal rate at higher spots and a lower removal rate at lower spots. Also, in another embodiment of the present invention is a pulsed-electrolytic process (260) in which positive and negative potentials are applied to the anodic and cathodic electrodes alternately, further encouraging surface planarization. AEP can be used either as a first step followed by a mechanical polish or a second step between initial CMP polish and a third step mechanical polish.

Abstract: A substrate preparation method is provided. The method includes providing a substrate to be prepared. The substrate has a first layer and a second layer. The first layer is to be removed from over the second layer. An energy frequency that is to be absorbed by the second layer while penetrating through the first layer transparently is determined. Energy that has the determined energy frequency is applied onto the first layer so as to disrupt a bond between the first layer and the second layer at a location of application of the energy. A portion of the first layer defined at the location of application of energy is removed. A substrate preparation apparatus is also provided.

Abstract: A substrate processing system is provided. The substrate processing system comprises a brush assembly that includes a core, a transducer, and a brush. The core is configured to include a plurality of orifices extending from a center of the brush core to an outer surface of the brush core. The transducer is configured to be disposed on an outer surface of the core. The transducer is capable of resonating at a high frequency. The brush includes a plurality of openings, and is configured to cover the transducer. When the transducer resonates at the high frequency, high energy acoustic energy is imparted from the transducer to a surface of a substrate to be prepared at a respective location of each opening of the plurality of openings.

Abstract: Provided is a system and method to prevent the transfer of accumulated fluid to wafers during cleaning operations. Specifically, when a wafer is secured by a plurality of self-draining edge wheels, any fluid contacting the self-draining edge wheels is channeled away from the wafer towards a bottom surface of each of the self-draining edge wheels. The channeling occurs by manufacturing the bottom portions of the self-draining edge wheels to have different configurations. The different configurations enhance fluid channeling away from the wafer. To further prevent fluid from wetting a bottom surface of the self-draining edge wheels, an edge wheel dryer can be positioned proximately adjacent to at least one self-draining edge wheel to suction fluid away from the bottom surface by using a vacuum channel of the edge wheel dryer.

Abstract: Among the many embodiment, in one embodiment, a method for processing a substrate is disclosed which includes generating a fluid layer on a surface of the substrate, the fluid layer defining a fluid meniscus. The generating includes moving a head in proximity to the surface, applying a fluid from the head to the surface while the head is in proximity to the surface of the substrate to define the fluid layer, and removing the fluid from the surface through the proximity head by a vacuum. The fluid travels along the fluid layer between the head and the substrate at a velocity that increases as the head is in closer proximity to the surface.

Abstract: An apparatus and method are disclosed in which a semiconductor substrate having a surface containing contaminants is cleaned or otherwise subjected to chemical treatment using a foam. The semiconductor wafer is supported either on a stiff support (or a layer of foam) and foam is provided on the opposite surface of the semiconductor wafer while the semiconductor wafer is supported. The foam contacting the semiconductor wafer is pressurized using a form to produce a jammed foam. Relative movement between the form and the semiconductor wafer, such as oscillation parallel and/or perpendicular to the top surface of the semiconductor wafer, is then induced while the jammed foam is in contact with the semiconductor wafer to remove the undesired contaminants and/or otherwise chemically treat the surface of the semiconductor wafer using the foam.

Abstract: An apparatus for use in processing a substrate includes a brush enclosure extending over a length. The brush enclosure is configured to be disposed over a surface of the substrate and has an open region that is configured to be disposed in proximity to the substrate. The open region extends over the length of the brush enclosure and enables foam from within the brush enclosure to contact the surface of the substrate. A substrate cleaning system and method for cleaning a substrate are also described.

Abstract: One of many embodiments of a substrate preparation system is provided which includes a head having a head surface where the head surface is proximate to a surface of the substrate. The system also includes a first conduit for delivering a first fluid to the surface of the substrate through the head, and a second conduit for delivering a second fluid to the surface of the substrate through the head, where the second fluid is different than the first fluid. The system also includes a third conduit for removing each of the first fluid and the second fluid from the surface of the substrate where the first conduit, the second conduit and the third conduit act substantially simultaneously.

Abstract: In advanced electrolytic polish (AEP) method, a metal wafer (10) acts as an anodic electrodes and another metal plate (65) is used as a cathodic electrode. A voltage differential is applied to the anode and cathode under a predetermined anodic dissolution current density. This causes a reaction that provides a planarized surface on the metal wafers. Additives are included in the electrolyte solution (55) which adsorb onto the wafer surface urging a higher removal rate at higher spots and a lower removal rate at lower spots. Also, in another embodiment of the present invention is a pulsed-electrolytic process (260) in which positive and negative potentials are applied to the anodic and cathodic electrodes alternately, further encouraging surface planarization. AEP can be used either as a first step followed by a mechanical polish or a second step between initial CMP polish and a third step mechanical polish.

Abstract: Metal CMP with reduced dishing and overpolish insensitivity is achieved with an abrasive-free polishing composition having a pH and oxidation-reduction potential in the domain of passivation of the metal and, therefore, a low static etching rate at high temperatures, e.g., higher than 50° C. Embodiments of the present invention comprise CMP of Cu film without any abrasive using a composition comprising one or more chelating agents, one or more oxidizers, one or more corrosion inhibitors, one or more agents to achieve a pH of about 3 to about 10 and deionized water.

Abstract: A method for performing electrochemical-mechanical planarization (EMP) of a workpiece surface including a pattern of electrical conductors comprises supplying a chemical-mechanical polishing (CMP)-type apparatus having an abrasive or non-abrasive polishing pad with an oxidizer-free, electrolytically conductive, abrasive or non-abrasive fluid and applying a time-varying anodic potential to the workpiece surface for controllably dissolving the material, e.g., metal, of the electrical conductors while simultaneously applying mechanical polishing action to the surface. The method advantageously reduces or substantially eliminates undesirable dishing characteristic of conventional CMP planarization processing utilizing chemical oxidizer agent(s). Apparatus for performing EMP are also disclosed.

Abstract: Metal CMP with reduced dishing and overpolish insensitivity is achieved with an abrasive-free polishing composition having a pH and oxidation-reduction potential in the domain of passivation of the metal and, therefore, a low static etching rate at high temperatures, e.g., higher than 50° C. Embodiments of the present invention comprise CMP of Cu film without any abrasive using a composition comprising one or more chelating agents, one or more oxidizers, one or more corrosion inhibitors, one or more agents to achieve a pH of about 3 to about 10 and deionized water.

Abstract: Metal CMP with reduced dishing and overpolish insensitivity is achieved with an abrasive-free polishing composition having a pH and oxidation-reduction potential in the domain of passivation of the metal and, therefore, a low static etching rate at high temperatures, e.g., higher than 50° C. Embodiments of the present invention comprise CMP of Cu film without any abrasive using a composition comprising one or more chelating agents, one or more oxidizers, one or more corrosion inhibitors, one or more agents to achieve a pH of about 3 to about 10 and deionized water.

Abstract: A cleaning solution and method for removing copper contaminants, slurry particles and other contaminants from the polished surfaces of copper interconnect structures are provided. The cleaning solution comprises various combinations of a plurality of the following components: a zeta potential modifier, a pH adjuster, a contamination remover and a corrosion inhibitor. A corrosion inhibitor remover also may be provided to remove the corrosion inhibitor following contamination removal with the cleaning solution. The cleaning solution components may be pre-mixed or the components may be delivered individually, either simultaneously or sequentially in any order, to the surface of a semiconductor wafer during cleaning.