Class / Patent application number | Description | Number of patent applications / Date published |
438678000 | Electroless deposition of conductive layer | 32 |
20080200030 | Method For Producing an Electronic Component - The invention relates to a method for producing an electronic component on a surface of a substrate with the electronic component having, seen at right angles to the surface of the substrate, at least two electrical functional layers which are arranged one above the other and such that they overlap at least in a surface area F, with the at least two electrical functional layers on the substrate being structured directly or indirectly using a continuous process, with a first electrical functional layer of the at least two electrical functional layers being structured such that a first length/width dimension of the first electrical functional layer parallel to the surface of the substrate and in a relative movement direction of the substrate is at least 5 μm longer/wider, preferably more than 1 mm longer/wider, than a length/width dimension of the surface area F in the relative movement direction and parallel to the surface of the substrate. | 08-21-2008 |
20080227293 | INTEGRATED CIRCUIT FABRICATION - A method for defining patterns in an integrated circuit comprises defining a plurality of features in a first photoresist layer using photolithography over a first region of a substrate. The method further comprises using pitch multiplication to produce at least two features in a lower masking layer for each feature in the photoresist layer. The features in the lower masking layer include looped ends. The method further comprises covering with a second photoresist layer a second region of the substrate including the looped ends in the lower masking layer. The method further comprises etching a pattern of trenches in the substrate through the features in the lower masking layer without etching in the second region. The trenches have a trench width. | 09-18-2008 |
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 |
20080280437 | Substrate Processing Method and Substrate Processing Apparatus - A CoWB film is formed as a cap metal on a Cu interconnection line formed on a substrate or wafer W, by repeating a plating step and a post-cleaning step a plurality of times. The plating step is arranged to apply electroless plating containing CoWB onto the Cu interconnection line. The post-cleaning step is arranged to clean the wafer W by use of a cleaning liquid, after the plating step. | 11-13-2008 |
20090017624 | Nodule Defect Reduction in Electroless Plating - An electroless plating method and the apparatus for performing the same are provided. The method includes providing a plating solution; contacting a front surface of the wafer with the plating solution; and incurring a plating reaction substantially simultaneously on an entirety of the front surface of the wafer. The step of incurring a plating reaction substantially simultaneously includes lift-dispense electroless plating and face-down immersion. | 01-15-2009 |
20090124081 | Techniques to Improve Characteristics of Processed Semiconductor Substrates - Techniques to improve characteristics of processed semiconductor substrates are described, including cleaning a substrate using a preclean process, the substrate comprising a dielectric region and a conductive region, introducing a hydroquinone to the substrate after cleaning the substrate using the preclean operation, and forming a capping layer over the conductive region of the substrate after introducing the hydroquinone. | 05-14-2009 |
20090142924 | REDUCED ELECTROMIGRATION AND STRESSED INDUCED MIGRATION OF CU WIRES BY SURFACE COATING - The idea of the invention is to coat the free surface of patterned Cu conducting lines in on-chip interconnections (BEOL) wiring by a 1-20 nm thick metal layer prior to deposition of the interlevel dielectric. This coating is sufficiently thin so as to obviate the need for additional planarization by polishing, while providing protection against oxidation and surface, or interface, diffusion of Cu which has been identified by the inventors as the leading contributor to metal line failure by electromigration and thermal stress voiding. Also, the metal layer increases the adhesion strength between the Cu and dielectric so as to further increase lifetime and facilitate process yield. The free surface is a direct result of the CMP (chemical mechanical polishing) in a damascene process or in a dry etching process by which Cu wiring is patterned. It is proposed that the metal capping layer be deposited by a selective process onto the Cu to minimize further processing. We have used electroless metal coatings, such as CoWP, CoSnP and Pd, to illustrate significant reliability benefits, although chemical vapor deposition (CVD) of metals or metal forming compounds can be employed. | 06-04-2009 |
20090298286 | Method of making electronic entities - Many electronic entities such as integrated circuits and discrete power devices have contact pads formed from successively deposited layers of nickel and a second metal such as gold. The resulting pad structure is used to make external electrical connection such as solder connection. Problems associated with failure of such connections are avoidable by inspecting the surface of the nickel layer for excessive small particle formation. | 12-03-2009 |
20100075498 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING THE SAME, AND PROCESSING LIQUID - A semiconductor device has interconnects protected with an alloy film having a minimum thickness necessary for producing the effect of preventing diffusion of oxygen, copper, etc., formed more uniformly over an entire surface of a substrate with less dependency to the interconnect pattern of the substrate. The semiconductor device includes, embedded interconnects, formed by filling an interconnect material into interconnect recesses formed in an electric insulator on a substrate, and an alloy film, containing 1 to 9 atomic % of tungsten or molybdenum and 3 to 12 atomic % of phosphorus or boron, formed by electroless plating on at least part of the embedded interconnects. | 03-25-2010 |
20100144144 | ELECTROLESS PLATING BATH COMPOSITION AND METHOD OF USE - An electroless plating composition comprising succinic acid, potassium carbonate, a source of cobalt metal ions, a reducing agent, and water is provided. An optional buffering agent may also be included in the composition. The composition may be used to deposit cobalt metal in or on semiconductor substrate surfaces including vias, trenches, and interconnects. | 06-10-2010 |
20110039410 | Apparatus and Method for Substrate Electroless Plating - A substrate is secured on a chuck that maintains a top surface of the substrate in a substantially level orientation. The chuck is positioned within a cavity of a vessel such that a body portion of the chuck is maintained in a spaced apart relationship with a surface of the cavity. An electroless plating solution is disposed in a region between the body portion of the chuck and the surface of the cavity such that an upper surface of the electroless plating solution is at a level lower than the substrate. The chuck is lowered within the cavity to cause the electroless plating solution to be displaced upward and flow over the top surface of the substrate in a substantially uniform manner from a periphery of the substrate to a center of the substrate. The chuck is then raised such that the electroless plating solution flows off of the substrate. | 02-17-2011 |
20110059610 | Method of using an electroless plating for depositing a metal seed layer for the subsequent plated backside metal film - A method of backside metal process for semiconductor electronic devices, particularly of using an electroless plating for depositing a metal seed layer for the plated backside metal film. The backside of a semiconductor wafer, with electronic devices already fabricated on the front side, is first coated with a thin metal seed layer by electroless plating. Then, the backside metal layer, such as a gold layer or a copper layer, is coated on the metal seed layer. The metal seed layer not only increases the adhesion between the front side metal layer and the backside metal layer through backside via holes, but also prevents metal peeling after subsequent fabrication processes. This is helpful for increasing the reliability of device performances. Suitable materials for the metal seed layer includes Pd, Au, Ni, Ag, Co, Cr, Cu, Pt, or their alloys, such as NiP, NiB, AuSn, Pt—Rh and the likes. | 03-10-2011 |
20110059611 | ELECTROLESS DEPOSITION OF BARRIER LAYERS - The invention relates to a solution for the deposition of barrier layers on metal surfaces, which comprises compounds of the elements nickel and molybdenum, at least one first reducing agent selected from among secondary and tertiary cyclic aminoboranes and at least one complexing agent, where the solution has a pH of from 8.5 to 12. | 03-10-2011 |
20110081779 | Method and Apparatus for Material Deposition - Broadly speaking, a method and an apparatus are provided for depositing a material on a semiconductor wafer (“wafer”). More specifically, the method and apparatus provide for selective heating of a surface of the wafer exposed to an electroless plating solution. The selective heating is provided by applying radiant energy to the wafer surface. The selective heating of the wafer surface causes a temperature increase at an interface between the wafer surface and the electroless plating solution. The temperature increase at the interface in turn causes a plating reaction to occur at the wafer surface. Thus, material is deposited on the wafer surface through an electroless plating reaction that is initiated and controlled by varying the temperature of the wafer surface using an appropriately defined radiant energy source. | 04-07-2011 |
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 |
20120196441 | SOLUTION AND METHOD FOR ACTIVATING THE OXIDIZED SURFACE OF A SEMICONDUCTOR SUBSTRATE - The present invention relates to a solution and a method for activating the oxidized surface of a substrate, in particular of a semiconducting substrate, for its subsequent coating by a metal layer deposited by the electroless method. | 08-02-2012 |
20120220126 | Selective Metal Deposition Over Dielectric Layers - Selective deposition of metal over dielectric layers in a manner that minimizes of eliminates keyhole formation is provided. According to one embodiment, a dielectric target layer is formed over a substrate layer, wherein the target layer may be configured as allow conformal metal deposition, and a dielectric second layer is formed over the target layer, wherein the second layer may be configured to allow bottom-up metal deposition. An opening may then be formed in the second layer and metal may be selectively deposited over substrate layer. | 08-30-2012 |
20120258595 | Formation of a Masking Layer on a Dielectric Region to Facilitate Formation of a Capping Layer on Electrically Conductive Regions Separated by the Dielectric Region - A masking layer is formed on a dielectric region of an electronic device so that, during subsequent formation of a capping layer on electrically conductive regions the masking layer inhibits formation of capping layer material on the dielectric region. The capping layer can be formed selectively on the electrically conductive regions or non-selectively; in either case, capping layer material formed over the dielectric region can subsequently be removed, thus ensuring that capping layer material is formed only on the electrically conductive regions. Silane-based materials, such as silane-based SAMs, can be used to form the masking layer. The capping layer can be formed of an electrically conductive, a semiconductor material, or an electrically insulative material, and can be formed using any appropriate process, including conventional deposition processes such as electroless deposition, chemical vapor deposition, physical vapor deposition or atomic layer deposition. | 10-11-2012 |
20130034959 | ELECTROLESS PLATING APPARATUS AND METHOD - An electroless plating apparatus and method designed specifically for plating at least one semiconductor wafer are disclosed. The apparatus comprises a container, a wafer holder, an electrolyte supplying unit, and an ultrasonic-vibration unit. The container is provided with at least an inlet and used for containing electrolyte. The wafer holder is provided within the container. The electrolyte supplying unit is used to supply the electrolyte into the container via the inlet. The ultrasonic-vibration unit consisting of at least one frequency ultrasonic transducer is disposed in the container for producing a uniform flow of electrolyte in the container. Thereby, the wafers can be uniformly plated, especially for wafers with fine via-holes or trench structures. | 02-07-2013 |
20130078808 | ELECTROLESS DEPOSITION SOLUTIONS AND PROCESS CONTROL - One embodiment of the present invention is a method of electroless deposition of cap layers for fabricating an integrated circuit. The method includes controlling the composition of an electroless deposition bath so as to substantially maintain the electroless deposition properties of the bath. Other embodiments of the present invention include electroless deposition solutions. Still another embodiment of the present invention is a composition used to recondition an electroless deposition bath. | 03-28-2013 |
20130084699 | Selective Metal Deposition Over Dielectric Layers - Selective deposition of metal over dielectric layers in a manner that minimizes of eliminates keyhole formation is provided. According to one embodiment, a dielectric target layer is formed over a substrate layer, wherein the target layer may be configured as allow conformal metal deposition, and a dielectric second layer is formed over the target layer, wherein the second layer may be configured to allow bottom-up metal deposition. An opening may then be formed in the second layer and metal may be selectively deposited over substrate layer. | 04-04-2013 |
20130122704 | ELECTROLESS PLATING APPARATUS AND ELECTROLESS PLATING METHOD - There is provided an electroless plating apparatus which, despite using a high-productivity batch processing method, can reduce the amount of a liquid chemical brought out of a processing tank, thereby reducing the cleaning time in a cleaning step, and can perform flushing easily and quickly. The electroless plating apparatus includes a pre-plating treatment module including a pre-plating treatment tank, a plating module, and an inter-module substrate transport device. The pre-plating treatment tank is provided with a pre-plating treatment solution circulation line having a temperature control function for a pre-plating treatment solution. The plating tank is provided with a plating solution circulation line having a filter and a temperature control function for a plating solution. The plating solution circulation line is connected to a flushing line for flushing the interior of the plating solution circulation line and the interior of the plating tank. | 05-16-2013 |
20130217227 | METHOD OF METAL DEPOSITION - A method of forming a metal layer on an electrically insulating substrate comprises depositing a photocatalyst layer onto the substrate and depositing a mask layer comprising voids on the substrate, such as a layer of latex microparticles with voids between them, to give an open pore structure to the mask. An electroless plating solution is then provided on the photocatalyst layer, and the photocatalyst layer and electroless plating solution are illuminated with actinic radiation whereby deposition of metal from the electroless plating solution to form a metal layer on the photocatalyst layer is initiated whereby the metal deposits in the voids of the mask layer. The mask layer is subsequently removed to leave a porous metal layer on the substrate. The method allows for deposition of porous metal films with controlled thickness and excellent adhesion onto electrically insulating substrates. The method is suitable for providing metal layers with controlled, regular porosity. | 08-22-2013 |
20130323926 | COMPOSITE MATERIAL, METHOD OF PRODUCING THE SAME, AND APPARATUS FOR PRODUCING THE SAME - Proposed are a composite material having a high adhesiveness, wherein non-penetrating pores that are formed in a silicone surface layer are filled up with a metal or the like without leaving any voids by using the plating technique and the silicone surface layer is coated with the metal or the like, and a method of producing the composite material. A composite material, which has a high adhesiveness between a second metal or an alloy of the second metal ( | 12-05-2013 |
20140087560 | METHOD OF DEPOSITING METALLIC LAYERS BASED ON NICKEL OR COBALT ON A SEMICONDUCTING SOLID SUBSTRATE; KIT FOR APPLICATION OF SAID METHOD - The present invention relates to a kit intended for the deposition of nickel or cobalt in the cavities of a semiconductor substrate intended to form through-silicon vias (TSV) for making interconnections in integrated circuits in three dimensions. | 03-27-2014 |
20140099789 | METHOD OF MAKING AN INTERCONNECT DEVICE - A semiconductor system includes: providing a dielectric layer; providing a conductor in the dielectric layer, the conductor exposed at the top of the dielectric layer; capping the exposed conductor; and modifying the surface of the dielectric layer, modifying the surface of the dielectric layer, wherein modifying the surface includes cleaning conductor ions from the dielectric layer by dissolving the conductor in a low pH solution, dissolving the dielectric layer under the conductor ions, mechanically enhanced cleaning, or chemisorbing a hydrophobic layer on the dielectric layer. | 04-10-2014 |
20140141609 | Process for Electroless Deposition of Gold and Gold Alloys on Silicon - A plating bath for electroless deposition of gold and gold alloy layers on such silicon-based substrates, includes Na(AuCl | 05-22-2014 |
20150140816 | PRE-TREATMENT METHOD FOR PLATING AND STORAGE MEDIUM - Catalytic metal nanoparticles can be attached on a base. A pre-treatment method for plating includes a catalytic particle-containing film forming process of forming a catalytic particle-containing film on a surface of a substrate by supplying, onto the substrate, a catalytic particle solution which is prepared by dispersing the catalytic metal nanoparticles and a dispersing agent in a solvent containing water; a first heating process of removing moisture contained at least in the catalytic particle-containing film by heating the substrate to a first temperature; and a second heating process of polymerizing the dispersing agent to have a sheet shape by heating the substrate to a second temperature higher than the first temperature after the first heating process and fixing the catalytic metal nanoparticles on a base layer by covering the catalytic metal nanoparticles with the sheet-shaped dispersing agent. | 05-21-2015 |
20150307993 | ELECTROLESS DEPOSITION OF CONTINUOUS COBALT LAYER USING COMPLEXED Ti3+ METAL IONS AS REDUCING AGENTS - A solution for electroless deposition of cobalt is provided. A reducing agent of Ti | 10-29-2015 |
20150307995 | ELECTROLESS DEPOSITION OF CONTINUOUS PALLADIUM LAYER USING COMPLEXED Co2+ METAL IONS OR Ti3+ METAL IONS AS REDUCING AGENTS - A solution for electroless deposition of palladium is provided. A reducing agent of Co | 10-29-2015 |
20150354064 | ELECTROLESS PLATING WITH AT LEAST TWO BORANE REDUCING AGENTS - A solution for providing electroless deposition of a metal layer on a substrate is provided. A solvent is provided. A metal precursor is provided to the solvent. A first borane containing reducing agent is provided to the solvent. A second borane containing reducing agent is provided to the solvent, wherein the first borane containing reducing agent has a deposition rate of at least five times a deposition rate of the second borane containing reducing agent, and wherein the solution is free of nonborane reducing agents. | 12-10-2015 |
20160189966 | PRE-FILL WAFER CLEANING FORMULATION - A pre-fill solution for application onto a substrate surface prior to a fill operation is provided, the fill operation defined by application of an electroless deposition solution onto the substrate surface to deposit a metallic material in an etched feature, the substrate surface having metallic contaminants generated from an etch operation that generated the etched feature in the substrate surface, the pre-fill solution effective for preventing the electroless deposition solution from depositing on the metallic contaminants, the pre-fill solution comprising: a surfactant, the surfactant configured to enhance wetting of the substrate surface, the concentration of the surfactant in the solution being approximately in the range of 10 ppm to 2000 ppm, wherein the surfactant is an amphoteric surfactant; oxalic acid dihydrate; and hypophosphorous acid as a pH adjusting agent configured to reduce the pH of the solution to approximately less than 2 during the application onto the substrate surface. | 06-30-2016 |