Abstract: A method of fabricating a chemical mechanical polishing pad includes introducing polymer precursors containing acrylate functional groups into a mold, providing abrasive particles and a photo-initiator in the polymer precursors to form a mixture, and while the mixture is contained between a bottom plate and a top cover of the mold, exposing the mixture to ultraviolet radiation through a transparent section of the mold to cause the polymer precursors to form radicals, forming a polymer matrix from the polymer precursor by causing the radicals to cross-link with one another. The polishing layer includes the polymer matrix having the abrasive particles dispersed therein.

Abstract: Embodiments of the present disclosure relate to advanced polishing pads with tunable chemical, material and structural properties, and new methods of manufacturing the same. According to one or more embodiments of the disclosure, it has been discovered that a polishing pad with improved properties may be produced by an additive manufacturing process, such as a three-dimensional (3D) printing process. Embodiments of the present disclosure thus may provide an advanced polishing pad that has discrete features and geometries, formed from at least two different materials that include functional polymers, functional oligomers, reactive diluents, and curing agents. For example, the advanced polishing pad may be formed from a plurality of polymeric layers, by the automated sequential deposition of at least one resin precursor composition followed by at least one curing step, wherein each layer may represent at least one polymer composition, and/or regions of different compositions.

Abstract: Embodiments of the present disclosure relate to advanced polishing pads with tunable chemical, material and structural properties, and new methods of manufacturing the same. According to one or more embodiments of the disclosure, it has been discovered that a polishing pad with improved properties may be produced by an additive manufacturing process, such as a three-dimensional (3D) printing process. Embodiments of the present disclosure thus may provide an advanced polishing pad that has discrete features and geometries, formed from at least two different materials that include functional polymers, functional oligomers, reactive diluents, and curing agents. For example, the advanced polishing pad may be formed from a plurality of polymeric layers, by the automated sequential deposition of at least one resin precursor composition followed by at least one curing step, wherein each layer may represent at least one polymer composition, and/or regions of different compositions.

Abstract: Embodiments of the disclosure generally provide polishing pads includes a composite pad body and methods for forming the polishing pads. One embodiment provides a polishing pad including a composite pad body. The composite pad body includes one or more first features formed from a first material or a first composition of materials, and one or more second features formed from a second material or a second composition of materials, wherein the one or more first features and the one or more second features are formed by depositing a plurality of layers comprising the first material or first composition of materials and second material or second composition of materials.

Abstract: Embodiments of the present disclosure relate to advanced polishing pads with tunable chemical, material and structural properties, and new methods of manufacturing the same. According to one or more embodiments of the disclosure, it has been discovered that a polishing pad with improved properties may be produced by an additive manufacturing process, such as a three-dimensional (3D) printing process. Embodiments of the present disclosure thus may provide an advanced polishing pad that has discrete features and geometries, formed from at least two different materials that include functional polymers, functional oligomers, reactive diluents, and curing agents. For example, the advanced polishing pad may be formed from a plurality of polymeric layers, by the automated sequential deposition of at least one resin precursor composition followed by at least one curing step, wherein each layer may represent at least one polymer composition, and/or regions of different compositions.

Abstract: A method of fabricating a polishing layer of a polishing pad includes successively depositing a plurality of layers with a 3D printer, each layer of the plurality of polishing layers deposited by ejecting a base material from a first nozzle and an additive material from a second nozzle and solidifying the base and additive material to form a solidified pad material.

Abstract: A polishing article manufacturing system includes a feed section and a take-up section, the take-up section comprising a supply roll having a polishing article disposed thereon for a chemical mechanical polishing process, a print section comprising a plurality of printheads disposed between the feed section and the take-up section, and a curing section disposed between the feed section and the take-up section, the curing section comprising one or both of a thermal curing device and an electromagnetic curing device.

Abstract: A polishing pad for chemical mechanical polishing is provided. The polishing pad includes a base region having a supporting surface. The polishing pad further includes a plurality of polishing features forming a polishing surface, the polishing surface opposing the supporting surface. The polishing pad further includes one or more channels formed in an interior region of the polishing pad and extending at least partly around a center of the polishing pad, wherein each channel is fluidly coupled to at least one port.

Abstract: Embodiments of the present apparatus and methods for post CMP clean. More particularly, embodiments provide apparatus and methods for removing nano sized particles. One embodiment provides a method for cleaning a substrate. The method includes exposing the substrate to a viscoelastic fluid to remove small particles from the substrate. The viscoelastic fluid comprising a viscosity adjustor and an aqueous base.

Abstract: A substrate for use in fabrication of an integrated circuit has a layer with a plurality of conductive interconnects. The substrate includes a semiconductor body, a dielectric layer disposed over the semiconductor body, a plurality of conductive lines of a conductive material disposed in first trenches in the dielectric layer to provide the conductive interconnects, and a closed conductive loop structure of the conductive material disposed in second trenches in the dielectric layer. The closed conductive loop is not electrically connected to any of the conductive lines.

Abstract: Among other things, a method comprises polishing a surface of a substrate by applying a pressure between the surface of a substrate and a surface of a polishing pad. The surface of the polishing pad defines one or more grooves separated by one or more partition regions. The one or more grooves have an initial depth before the polishing starts and extend from an initial outer surface of the one or more partition regions to an initial bottom of the one or more grooves. The method also comprises removing material below an initial bottom of the one or more grooves such that a distance between an outer surface of the one or more partition regions and a bottom of the one or more grooves remain substantially the same as the initial depth.

Abstract: A method for cleaning a substrate is provided. The method initiates with disposing a fluid layer having solid components therein to a surface of the substrate. A shear force directed substantially parallel to the surface of the substrate and toward an outer edge of the substrate is then created. The shear force may result from a normal or tangential component of a force applied to a solid body in contact with the fluid layer in one embodiment. The surface of the substrate is rinsed to remove the fluid layer. A cleaning system and apparatus are also provided.

Abstract: An apparatus for cleaning a substrate is disclosed. The apparatus having a first head unit and a second head unit. The first head unit is positioned proximate to the surface of the substrate and has a first row of channels defined within configured to supply a foam to the surface of the substrate. The second head unit is positioned substantially adjacent to the first head unit and proximate to the surface of the substrate. A second and a third row of channels are defined within the second head unit. The second row of channels is configured to supply a fluid to the surface of the substrate. The third row of channels is configured to apply a vacuum to the surface of the substrate.

Abstract: Methods adapted to clean a chemical mechanical polishing (CMP) pad are disclosed. The methods include positioning an energized fluid delivery assembly over a CMP polishing pad; rotating the polishing pad on a platen; energizing a fluid within the energized fluid delivery assembly; applying the energized fluid to the polishing pad to dislodge slurry residue and debris; and removing the dislodged slurry residue and debris using a vacuum suction unit. Systems and apparatus for carrying out the methods are provided, as are numerous additional aspects.

Abstract: In one embodiment, a polishing pad includes a hydrophilic polymer base having a polishing surface, and a metal oxide coating. The metal oxide coating has nanoparticles of metal oxide disposed on the polishing surface. In another embodiment, a processing station includes a rotatable platen, a polishing head, and a precursor delivery system. The polishing head is configured to retain a substrate against the polishing pad. The precursor delivery system is configured to form an oxide coating on a surface of a polishing pad disposed on the platen. In yet another embodiment, a method for modifying a surface of a polishing pad includes wetting the surface of the polishing pad and delivering a precursor to the wetted surface of the polishing pad surface. The method also includes forming a metal oxide coating having nanoparticles of metal oxide on the surface from the precursor.

Abstract: A method for cleaning a substrate is provided. In this method, a flow of non-Newtonian fluid is provided where at least a portion of the flow exhibits plug flow. To remove particles from a surface of the substrate, the surface of the substrate is placed in contact with the portion of the flow that exhibits plug flow such that the portion of the flow exhibiting plug flow moves over the surface of the substrate. Additional methods and apparatuses for cleaning a substrate also are described.

Abstract: Material for cleaning using a tri-state body are disclosed. A substrate having a particle deposited thereon is provided. A tri-state body that has a solid portion, liquid portion, and a gas portion is generated. A force is applied over the tri-state body to promulgate an interaction between the solid portion and the particle. The tri-state body is removed along with the particle from the surface of the substrate. The interaction between the solid portion and the particle causes the particle to be removed along with the tri-state body.

Abstract: An apparatus for cleaning a substrate includes an application unit having a top inlet conduit and a bottom plate section. The top inlet conduit has an opening for receiving a non-Newtonian fluid and the bottom plate section has an opening through which the non-Newtonian fluid can flow. The bottom plate section is perpendicular to the top inlet conduit, and a surface of the bottom plate section is disposed above and parallel to a surface of a substrate so as to define a gap between the surface of the bottom plate section and the surface of the substrate. The defined gap has a height configured to create a flow of the non-Newtonian fluid in which a portion of the flow exhibits plug flow, and the plug flow moves over the surface of the substrate to remove particles from the surface of the substrate.

Abstract: An apparatus for processing a substrate is provided. The apparatus includes a solid material having a support side and a contact side. The contact side has an outer surface, and the outer surface is configured to become softer relative to a remainder of the solid material when exposed to an activation solution. The apparatus includes a support structure configured to support the solid material from the support side of the solid material, such that the contact side of the solid material is oriented to face a surface of the substrate, when the substrate is present. Also provided is a gimbaled structure connected to the support structure. The gimbaled structure enabling the outer surface of the contact side to substantially align in a coplanar arrangement with the surface of the substrate, when the substrate is present. A force application structure is coupled to the gimbaled structure.

Abstract: A method is provided for removing contamination from a substrate. The method includes applying a cleaning solution having a dispersed phase, a continuous phase and particles dispersed within the continuous phase to a surface of the substrate. The method includes forcing one of the particles dispersed within the continuous phase proximate to one of the surface contaminants. The forcing is sufficient to overcome any repulsive forces between the particles and the surface contaminants so that the one of the particles and the one of the surface contaminants are engaged. The method also includes removing the engaged particle and surface contaminant from the surface of the substrate. A process to manufacture the cleaning material is also provided.