Patent application number | Description | Published |
20080227369 | Apparatus and Method for Confined Area Planarization - A proximity head and associated method of use is provided for performing confined area planarization of a semiconductor wafer. The proximity head includes a chamber defined to maintain an electrolyte solution. A cathode is disposed within the chamber in exposure to the electrolyte solution. A cation exchange membrane is disposed over a lower opening of the chamber. A top surface of the cation exchange membrane is in direct exposure to the electrolyte solution to be maintained within the chamber. A fluid supply channel is defined to expel fluid at a location adjacent to a lower surface of the cation exchange membrane. A vacuum channel is defined to provide suction at a location adjacent to the lower surface of the cation exchange membrane, such that the fluid to be expelled from the fluid supply channel is made to flow over the lower surface of the cation exchange membrane. | 09-18-2008 |
20080245390 | Method for cleaning semiconductor wafer surfaces by applying periodic shear stress to the cleaning solution - Systems and methods for cleaning particulate contaminants adhered to wafer surfaces are provided. A cleaning media including dispersed coupling elements suspended within the cleaning media is applied over a wafer surface. External energy is applied to the cleaning media to generate periodic shear stresses within the media. The periodic shear stresses impart momentum and/or drag forces on the coupling elements causing the coupling elements to interact with the particulate contaminants to remove the particulate contaminants from the wafer surfaces. | 10-09-2008 |
20080251148 | Fluid Handling System for Wafer Electroless Plating and Associated Methods - A chemical fluid handling system is defined to supply a number of chemicals to a number of fluid inputs of a mixing manifold. The chemical fluid handling system includes a number of fluid recirculation loops for separately pre-conditioning and controlling the supply of each of the number of chemicals. Each of the fluid recirculation loops is defined to degas, heat, and filter a particular one of the number of chemical components. The mixing manifold is defined to mix the number of chemicals to form the electroless plating solution. The mixing manifold includes a fluid output connected to a supply line. The supply line is connected to supply the electroless plating solution to a fluid bowl within an electroless plating chamber. | 10-16-2008 |
20080254225 | Method and Apparatus for Wafer Electroless Plating - A semiconductor wafer electroless plating apparatus includes a platen and a fluid bowl. The platen has a top surface defined to support a wafer, and an outer surface extending downward from a periphery of the top surface to a lower surface of the platen. The fluid bowl has an inner volume defined by an interior surface so as to receive the platen, and wafer to be supported thereon, within the inner volume. A seal is disposed around the interior surface of the fluid bowl so as to form a liquid tight barrier when engaged between the interior surface of the fluid bowl and the outer surface of the platen. A number of fluid dispense nozzles are positioned to dispense electroplating solution within the fluid bowl above the seal so as to rise up and flow over the platen, thereby flowing over the wafer when present on the platen. | 10-16-2008 |
20080254621 | Wafer Electroless Plating System and Associated Methods - A dry-in/dry-out system is disclosed for wafer electroless plating. The system includes an upper zone for wafer ingress/egress and drying operations. Proximity heads are provided in the upper zone to perform the drying operations. The system also includes a lower zone for electroless plating operations. The lower zone includes an electroless plating apparatus that implements a wafer submersion by fluid upwelling method. The upper and lower zones of the system are enclosed by a dual-walled chamber, wherein the inner wall is a chemically inert plastic and the outer wall is a structural metal. The system interfaces with a fluid handling system which provides the necessary chemistry supply and control for the system. The system is ambient controlled. Also, the system interfaces with an ambient controlled managed transfer module (MTM). | 10-16-2008 |
20080260940 | APPARATUS AND METHOD FOR INTEGRATED SURFACE TREATMENT AND DEPOSITION FOR COPPER INTERCONNECT - A method and system for depositing films on a substrate for copper interconnect in an integrated system is provided. The method includes moving the substrate into a processing chamber having a plurality of proximity heads. Selected ones of the proximity heads is configured to perform at least one of surface treatments and atomic layer depositions (ALDs). The processing chamber is part of the integrated system. Within the processing chamber, barrier layer deposition is performed over a surface of the substrate using one of the plurality of proximity heads functioning to perform barrier layer ALD. In addition, the method includes moving the substrate from the processing chamber, through a transfer module of the integrated system and into a processing module for performing copper seed layer deposition. The processing module for performing copper seed layer deposition is part of the integrated system. Within the processing module for performing copper seed layer deposition, copper seed layer deposition is performed over the surface of the substrate. The integrated system enables controlled-ambient transitions within the integrated system to limit exposure of the substrate to uncontrolled ambient conditions outside of the integrated system. | 10-23-2008 |
20080260963 | APPARATUS AND METHOD FOR PRE AND POST TREATMENT OF ATOMIC LAYER DEPOSITION - The embodiments fill the needs of systems and processes that perform substrate surface treatment to provide homogenous, clean, and sometimes activated surface in order to provide good adhesion between layers to improve metal migration and void propagation. In an exemplary embodiment, a proximity head for treating a substrate surface is provided. The proximity head is configured to dispense a treatment gas to treat an active process region of a substrate surface under the proximity head. The proximity head covers the action process region of the substrate surface and the proximity head includes at least one vacuum channel to pull excess treatment gas from a reaction volume between the proximity head and the substrate. The proximity head has an excitation chamber to excite the treatment gas before the treatment gas being dispensed on the active process region portion of the substrate surface. | 10-23-2008 |
20080260967 | APPARATUS AND METHOD FOR INTEGRATED SURFACE TREATMENT AND FILM DEPOSITION - The embodiments fill the needs of systems and processes that perform substrate surface treatment to provide homogenous, clean, and sometimes activated surface in order to provide good adhesion between layers to improve metal migration and void propagation. In one exemplary embodiment, a chamber for performing surface treatment and film deposition is provided. The chamber includes a first proximity head for substrate surface treatment configured to dispense a first treatment gas to treat a portion of a surface of a substrate under the first proximity head for substrate surface treatment. The chamber also includes a first proximity head for atomic layer deposition (ALD) configured to sequentially dispensing a first reactant gas and a first purging gas to deposit a first ALD film under the second proximity head for ALD. | 10-23-2008 |
20080261412 | APPARATUS AND METHOD FOR ATOMIC LAYER DEPOSITION - The embodiments provide apparatus and methods of depositing conformal thin film on interconnect structures by providing processes and systems using an atomic layer deposition (ALD). More specifically, each of the ALD systems includes a proximity head that has a small reaction volume right above an active process region of the substrate surface. The proximity head small amount of reactants and purging gas to be distributed and pumped away from the small reaction volume between the proximity head and the substrate in relatively short periods, which increases the through-put. In an exemplary embodiment, a proximity head for dispensing reactants and purging gas to deposit a thin film by atomic layer deposition (ALD) is provided. The proximity head is configured to sequentially dispensing a reactant gas and a purging gas to deposit a thin ALD film under the proximity head. The proximity head covers an active process region of a substrate surface. The proximity head also includes at least one vacuum channel to pull excess reactant gas, purging gas, or deposition byproducts from a reaction volume between a surface of the proximity head facing the substrate and the substrate. The proximity includes a plurality of sides, each side being configured to dispense either a reactant gas or a purging gas on the substrate surface underneath the proximity head. Each side has at least one vacuum channel. | 10-23-2008 |
20080271749 | Substrate cleaning technique employing multi-phase solution - A method and system for cleaning opposed surfaces of a semiconductor wafer having particulate matter thereon. The method includes generating relative movement between a fluid and the substrate. The relative movement is in a direction that is transverse to a normal to one of the opposed surfaces and creates two spaced-apart flows. Each of the flows is adjacent to one of the opposed surfaces that is different from the opposed surface that is adjacent to the remaining flow of the plurality of flows. The fluid has coupling elements entrained therein, and the relative movement is established to impart sufficient drag upon a subset of the coupling elements to create movement of the coupling elements of the subset within the fluid. In this manner, a quantity of the drag is imparted upon the particulate matter to cause the particulate matter to move with respect to the substrate. | 11-06-2008 |
20080280456 | Thermal methods for cleaning post-CMP wafers - Methods for cleaning semiconductor wafers following chemical mechanical polishing are provided. An exemplary method exposes a wafer to a thermal treatment in an oxidizing environment followed by a thermal treatment in a reducing environment. The thermal treatment in the oxidizing environment both removes residues and oxidizes exposed copper surfaces to form a cupric oxide layer. The thermal treatment in the reducing environment then reduces the cupric oxide to elemental copper. This leaves the exposed copper clean and in condition for further processing, such as electroless plating. | 11-13-2008 |
20090134520 | PROCESS INTEGRATION SCHEME TO LOWER OVERALL DIELECTRIC CONSTANT IN BEOL INTERCONNECT STRUCTURES - Back-End of Line (BEoL) interconnect structures, and methods for their manufacture, are provided. The structures are characterized by narrower conductive lines and reduced overall dielectric constant values. Conformal diffusion barrier layers, and selectively formed capping layers, are used to isolate the conductive lines and vias from surrounding dielectric layers in the interconnect structures. The methods of the invention employ techniques to narrow the openings in photoresist masks in order to define narrower vias. More narrow vias increase the amount of misalignment that can be tolerated between the vias and the conductive lines. | 05-28-2009 |
20090304914 | Self assembled monolayer for improving adhesion between copper and barrier layer - The embodiments fill the need enabling deposition of a thin and conformal barrier layer, and a copper layer in the copper interconnect with good electro-migration performance and with reduced risk of stress-induce voiding of copper interconnect. Electromigration and stress-induced voiding are affected by the adhesion between the barrier layer and the copper layer. A functionalization layer is deposited over the barrier layer to enable the copper layer being deposit in the copper interconnect. The functionalization layer forms strong bonds with barrier layer and with copper to improve adhesion property between the two layers. An exemplary method of preparing a substrate surface of a substrate to deposit a functionalization layer over a metallic barrier layer of a copper interconnect to assist deposition of a copper layer in the copper interconnect in order to improve electromigration performance of the copper interconnect is provided. The method includes depositing the metallic barrier layer to line the copper interconnect structure in the integrated system, and oxidizing a surface of the metallic barrier layer. The method also includes depositing the functionalization layer over the oxidized surface of the metallic barrier layer, and depositing the copper layer in the copper interconnect structure after the funcationalization layer is deposited over the metallic barrier layer. | 12-10-2009 |
20090320749 | APPARATUS FOR INTEGRATED SURFACE TREATMENT AND DEPOSITION FOR COPPER INTERCONNECT - An integrated system for depositing films on a substrate for copper interconnect is provided. The system includes a processing chamber with a plurality of proximity heads, and a vacuum transfer module coupled to the processing chamber. Selected ones of the proximity heads are used for surface treatments and atomic layer depositions (ALDs). The system further includes a processing module for copper seed layer deposition, which is integrated with a rinse/dryer to enable dry-in/dry-out process capability and is filled with an inert gas to limit the exposure of the substrate to oxygen. Additionally, the system includes a controlled-ambient transfer module coupled to the processing module for copper seed layer deposition. Further, the system includes a loadlock coupled to the vacuum transfer module and to the controlled-ambient transfer module. The integrated system enables controlled-ambient transitions within the system to limit exposure of the substrate to uncontrolled ambient conditions outside of the system. | 12-31-2009 |
20100136788 | THERMAL METHODS FOR CLEANING POST-CMP WAFERS - Methods for cleaning semiconductor wafers following chemical mechanical polishing are provided. An exemplary method exposes a wafer to a thermal treatment in an oxidizing environment followed by a thermal treatment in a reducing environment. The thermal treatment in the oxidizing environment both removes residues and oxidizes exposed copper surfaces to form a cupric oxide layer. The thermal treatment in the reducing environment then reduces the cupric oxide to elemental copper. This leaves the exposed copper clean and in condition for further processing, such as electroless plating. | 06-03-2010 |
20100239767 | Apparatus for Applying a Plating Solution for Electroless Deposition - An electroless plating chamber is provided. The electroless plating chamber includes a chuck configured to support a substrate and a bowl surrounding a base and a sidewall of the chuck. The base has an annular channel defined along an inner diameter of the base. The chamber includes a drain connected to the annular channel. The drain is capable of removing fluid collected from the chuck. A proximity head capable of cleaning and substantially drying the substrate is included in the chamber. A method for performing an electroless plating operation is also provided. | 09-23-2010 |
20100319726 | SUBSTRATE PREPARATION USING MEGASONIC COUPLING FLUID MENISCUS - A method for cleaning a substrate is provided. The method includes receiving the substrate using a carrier that forms a circular opening, the substrate being positioned in the circular opening of the carrier. The holding of the substrate enables exposure of both a first side and a second side of the substrate at a same time. Then, moving the substrate along a direction, and while moving the substrate: (i) applying a chemistry onto the first side of the substrate, where the first side of the substrate having material to be removed; (ii) forming a fluid meniscus against the second side of the substrate at a location that is opposite a location onto which the chemistry is applied; and (iii) applying megasonic energy to the fluid meniscus while the fluid meniscus is applied against the second side. The megasonic energy increases mass transport of the chemistry to enhance removal of the material to be removed from the first side. | 12-23-2010 |
20110011335 | Electroless Plating Method and Apparatus - An electroless plating system is provided. The system includes a first vacuum chuck supporting a first wafer and a second vacuum chuck supporting a second wafer such that a top surface of the second wafer is opposing a top surface of the first wafer. The system also includes a fluid delivery system configured to deliver a plating solution to the top surface of the first wafer, wherein in response to delivery of the plating solution, the top surface of the second wafer is brought proximate to the top surface of the first wafer so that the plating solution contacts both top surfaces. A method for applying an electroless plating solution to a substrate is also provided. | 01-20-2011 |
20110306203 | INTERCONNECT STRUCTURE AND METHOD OF MANUFACTURING A DAMASCENE STRUCTURE - An interconnect structure is provided, including a layer of dielectric material having at least one opening and a first barrier layer on sidewalls defining the opening. A ruthenium-containing second barrier layer overlays the first barrier layer, the second barrier layer having a ruthenium zone, a ruthenium oxide zone, and a ruthenium-rich zone. The ruthenium zone is interposed between the first barrier layer and the ruthenium oxide zone. The ruthenium oxide zone is interposed between the ruthenium zone and the ruthenium-rich zone. | 12-15-2011 |
20120045897 | Wafer Electroless Plating System and Associated Methods - A dry-in/dry-out system is disclosed for wafer electroless plating. The system includes an upper zone for wafer ingress/egress and drying operations. Proximity heads are provided in the upper zone to perform the drying operations. The system also includes a lower zone for electroless plating operations. The lower zone includes an electroless plating apparatus that implements a wafer submersion by fluid upwelling method. The upper and lower zones of the system are enclosed by a dual-walled chamber, wherein the inner wall is a chemically inert plastic and the outer wall is a structural metal. The system interfaces with a fluid handling system which provides the necessary chemistry supply and control for the system. The system is ambient controlled. Also, the system interfaces with an ambient controlled managed transfer module (MTM). | 02-23-2012 |
20120248219 | APPARATUS AND METHOD FOR ATOMIC LAYER DEPOSITION - A proximity heads for dispensing reactants and purging gas to deposit a thin film by Atomic Layer Deposition (ALD) includes a plurality of sides. Extending over a portion of the substrate region and being spaced apart from the portion of the substrate region when present, the proximity head is rotatable so as to place each side in a direction of the substrate region, and is disposed in a vacuum chamber coupled to a carrier gas source to sustain a pressure for the proximity head during operation. Each side of the proximity head includes a gas conduit through which the reactant gas and the purging gas are sequentially dispensed, and at least two separate vacuum conduits on each side of the gas conduit to pull excess reactant gas, purging gas, or deposition byproducts from a reaction volume between a surface of the proximity head facing the substrate and the substrate. | 10-04-2012 |
20120269987 | Processes and Systems for Engineering a Barrier Surface for Copper Deposition - An integrated system for processing a substrate in controlled environment to enable deposition of a thin copper seed layer on a surface of a metallic barrier layer of a copper interconnect is provided. The system includes a lab-ambient transfer chamber, a vacuum transfer chamber, a vacuum process module for cleaning an exposed surface of a metal oxide of a underlying metal, a vacuum process module for depositing the metallic barrier layer, and a controlled-ambient transfer chamber filled with an inert gas, wherein at least one controlled-ambient process module is coupled to the controlled-ambient transfer chamber. In addition, the system includes an electroless copper deposition process module used to deposit the thin layer of copper seed layer on the surface of the metallic barrier layer. | 10-25-2012 |
20130040460 | METHODS FOR ATOMIC LAYER DEPOSITION - A method of depositing a thin film by atomic layer deposition (ALD) on a substrate surface is disclosed. The disclosed method includes placing an ALD deposition proximity head above the substrate with at least one gas channel configured to dispense a gas to an active process region of the substrate surface. The ALD deposition proximity head extends over and is being spaced apart from the active process region of the substrate surface when present. After a pulse of a first reactant gas is dispensed on the active process region of the substrate surface underneath the proximity head, a pulse of a second reactant gas is dispensed on the active process region of the substrate surface underneath the proximity head to react with the first reactant gas to form a portion of the thin layer of ALD film on the surface of substrate underneath the proximity head. | 02-14-2013 |
20130061887 | METHOD FOR REMOVING MATERIAL FROM SEMICONDUCTOR WAFER AND APPARATUS FOR PERFORMING THE SAME - 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. | 03-14-2013 |
20130206182 | SUBSTRATE CLEANING TECHNIQUE EMPLOYING MULTI-PHASE SOLUTION - Apparatus, methods, and computer programs for cleaning opposed surfaces of a semiconductor wafer are presented. One apparatus includes first, second, and third valves, and one or more second drains. The first valves are coupled to a supply of rinsing solution and to first throughways that are coupled to an immersion tank above a region in the immersion tank, the region being defined by an area occupied by the substrate when the substrate is disposed vertically on a support within the immersion tank. The second valves are coupled to first drains and to second throughways that are coupled to the immersion tank below the region, and the third valves are coupled to a supply of cleaning solution and to third throughways that are coupled to the immersion tank below the region. Further, the second drains are coupled to fourth throughways that are coupled to the immersion tank above the region. | 08-15-2013 |
20130280917 | Method and Apparatus for Wafer Electroless Plating - A semiconductor wafer electroless plating apparatus includes a platen and a fluid bowl. The platen has a top surface defined to support a wafer, and an outer surface extending downward from a periphery of the top surface to a lower surface of the platen. The fluid bowl has an inner volume defined by an interior surface so as to receive the platen, and wafer to be supported thereon, within the inner volume. A seal is disposed around the interior surface of the fluid bowl so as to form a liquid tight barrier when engaged between the interior surface of the fluid bowl and the outer surface of the platen. A number of fluid dispense nozzles are positioned to dispense electroplating solution within the fluid bowl above the seal so as to rise up and flow over the platen, thereby flowing over the wafer when present on the platen. | 10-24-2013 |
20140322446 | PROCESSES AND SYSTEMS FOR ENGINEERING A COPPER SURFACE FOR SELECTIVE METAL DEPOSITION - An integrated system for transferring and processing a substrate in a controlled environment to enable selective deposition of a thin layer of a cobalt-alloy material on a copper surface of a copper interconnect to improve electromigration performance of the copper interconnect, comprising: a lab-ambient transfer chamber; a substrate cleaning reactor coupled to the lab-ambient transfer chamber, wherein the substrate cleaning reactor cleans the substrate surface to remove metal-organic complex contaminants on the substrate surface; a vacuum transfer chamber; a vacuum process module for removing organic contaminants from the substrate surface; a controlled-ambient transfer chamber filled with an inert gas; and an electroless cobalt-alloy material deposition process module used to deposit the thin layer of cobalt-alloy material on the copper surface of the copper interconnect after the substrate surface has been removed of metallic contaminants and organic contaminants, and the copper surface has been removed of copper oxide. | 10-30-2014 |