Abstract: A semiconductor device is provided. The semiconductor device includes first metal lines on a lower layer, a dielectric barrier layer provided on the lower layer to cover side and top surfaces of the first metal lines, an etch stop layer provided on the dielectric barrier layer to define gap regions between the first metal lines, an upper insulating layer on the etch stop layer, and a conductive via penetrating the upper insulating layer, the etch stop layer, and the dielectric barrier layer to contact a top surface of a first metal line. The etch stop layer includes first portions on the first metal lines and second portions between the first metal lines. The second portions of the etch stop layer are higher than the first portions.

Abstract: One aspect of the present invention includes a method of fabricating an electronic device. According to one embodiment, the method comprises providing a substrate having dielectric oxide surface areas adjacent to electrically conductive surface areas, chemically bonding an anchor compound with the dielectric oxide surface areas so as to form an anchor layer, initiating the growth of a metal using the electrically conductive surface areas and growing the metal so that the anchor layer also bonds with the metal. The anchor compound has at least one functional group capable of forming a chemical bond with the oxide surface and has at least one functional group capable of forming a chemical bond with the metal. Another aspect of the present invention is an electronic device. A third aspect of the present invention is a solution comprising the anchor compound.

Abstract: The surface of silicon is textured to create black silicon on a nano-micro scale by electrochemical reduction of a silica layer on silicon in molten salts. The silica layer can be a coating, or a layer caused by the oxidation of the silicon.

Abstract: Methods and apparatuses for fabricating three-dimensional integrated circuits having through hole vias are provided. One aspect of the present invention is a method of gapfill for through hole vias for three-dimensional integrated circuits. The method comprises providing a semiconductor wafer having a plurality of holes for through hole vias and depositing a conformal metal layer to partially fill the holes to leave open voids. The method also includes purging the voids and cleaning the surface of the voids and using a dry deposition process to fill or close the voids. Another aspect of the present invention is an electronic device structure for a three-dimensional integrated circuit.

Abstract: The method utilizes a conducting trench base with non-conducting trench walls to corral charged particles precisely into the trenches. The nanoparticles are close packed in the channels and highly ordered. This approach utilizes the charge on the particles to selectively deposit them within the trenches, as all nanoparticles in solution can be charged, and this can be extended to any nanoparticle system beyond gold. Also, this method results in the layer-by-layer growth of the gold nanoparticles. Therefore the depth of the nanoparticle layers within the trenches is controllable. This allows the possibility of heterolayered structures of different nanoparticle layers. Further this method ensures that assembly occurs to fill the void space available provided the back-contacting electrode is more conducting than the trench walls. This allows nanoparticle assemblies to be corralled into any lithographically defined shape, which makes this approach highly adaptable to a range of applications.

Abstract: In one disclosed embodiment, the present method for depositing a conductive capping layer on metal lines comprises forming metal lines on a dielectric layer, applying a voltage to the metal lines, and depositing the conductive capping layer on the metal lines. The applied voltage increases the selectivity of the deposition process used, thereby preventing the conductive capping layer from causing a short between the metal lines. The conductive capping layer may be deposited through electroplating, electrolessly, by atomic layer deposition (ALD), or by chemical vapor deposition (CVD), for example. In one embodiment, the present method is utilized to fabricate a semiconductor wafer. In one embodiment, the metal lines comprise copper lines, while the conductive capping layer may comprise tantalum or cobalt. The present method enables deposition of a capping layer having high electromigration resistance.

Abstract: The mechanisms of preparing bump structures described by using patterned anodes may simplify bump-making process, reduce manufacturing cost, and improve thickness uniformity within die and across the wafer. In addition, the mechanisms described above allow forming bumps with different heights to allow bumps to be integrated with elements on a substrate with different heights. Bumps with different heights expand the application of copper post bumps to enable further chip integration.

Abstract: A capacitive electromechanical transducer includes a substrate, a cavity formed by a vibrating membrane held above the substrate with a certain distance between the vibrating membrane and the substrate by supporting portions arranged on the substrate, a first electrode whose surface is exposed to the cavity, and a second electrode whose surface facing the cavity is covered with an insulating film, wherein the first electrode is provided on a surface of the substrate or a lower surface of the vibrating membrane and the second electrode is provided on a surface of the vibrating membrane or a surface of the substrate so as to face the first electrode. In this transducer, fine particles composed of an oxide film of a substance constituting the first electrode are arranged on the surface of the first electrode, and the diameter of the fine particles is 2 to 200 nm.

Abstract: A method for manufacturing a semiconductor device includes forming a laminated structure of a plurality of metal films on a semiconductor substrate using an electroless plating method. The forming of the metal films includes: performing an electroless plating process including a reduction reaction using a first plating tank; and performing an electroless plating process by only a substitution reaction using a second plating tank. The electroless plating process including the reduction reaction that is performed using the first plating tank is performed in a shading environment, and the electroless plating process performed by only the substitution reaction using the second plating tank is performed in a non-shading environment.

Abstract: Provided is a method of manufacturing an electronic device having a first electronic component having a first terminal and a second electronic component having a second terminal, wherein the first electric component is electrically connected to the second electronic component by connecting the first terminal to the second terminal with solder, the method including: providing a resin layer having a flux action between the first terminal and the second terminal to obtain a laminate including the first electronic component, the second electronic component, and the resin layer, wherein a solder is provided on the first terminal or the second terminal; soldering the first terminal and the second terminal; and curing the resin layer while pressing the laminate with a pressurized fluid.

Abstract: The present invention relates to a process for producing an electronic device having two contacts, an anode and a cathode being completely or partly transmissive to light, one or more organic semi-conducting layers and one or more organic buffer layers between the contacts or the cathode and anode respectively. A solution is sprayed which contains organic material for applying at least one porous layer.

Abstract: The manufacturing method of the present invention includes steps of selectively forming a photocatalyst material or a material including an amino group by discharging a composition including the photocatalyst material or the material including an amino group; immersing the photocatalyst material or the material including an amino group in a solution including a plating catalyst material so as to adsorb or deposit the plating catalyst material onto the photocatalyst material or the material including an amino group; and immersing the plating catalyst material in a plating solution including a metal material so as to form a metal film on a surface of the photocatalyst material or the material including an amino group adsorbing or depositing the plating catalyst material, thereby manufacturing a semiconductor device. The pH of the solution including the plating catalyst material is adjusted in a range of 3 to 6.

Abstract: As a semiconductor device, specifically, a pixel portion included in a semiconductor device is made to have higher precision and higher aperture ratio, it is required to form a smaller wiring in width. In the case of forming a wiring by using an ink-jet method, a dot spreads on a wiring formation surface, and it is difficult to narrow width of a wiring. In the present invention, a photocatalytic substance typified by TiO2 is formed on a wiring formation surface, and a wiring is formed by utilizing photocatalytic activity of the photocatalytic substance. According to the present invention, a narrower wiring, that is, a smaller wiring in width than a diameter of a dot formed by an ink-jet method can be formed.

Abstract: Methods are provided for multi-step Cu metal plating on a continuous Ru metal film in recessed features found in advanced integrated circuits. The use of a continuous Ru metal film prevents formation of undesirable micro-voids during Cu metal filling of high-aspect-ratio recessed features, such as trenches and vias, and enables formation of large Cu metal grains that include a continuous Cu metal layer plated onto the continuous Ru metal film. The large Cu grains lower the electrical resistivity of the Cu filled recessed features and increase the reliability of the integrated circuit.

Abstract: A method of forming a device includes performing a first plating process to form a first metallic feature, and performing an activation treatment to a surface of the first metallic feature in an activation treatment solution, wherein the activation treatment solution includes a treatment agent in de-ionized (DI) water. After the step of performing the activation treatment, performing a second plating process to form a second metallic feature and contacting the surface of the first metallic feature.

Abstract: There is provided a backplane for an organic electronic device. The backplane has a TFT substrate having a multiplicity of electrode structures thereon. There are spaces around the electrode structures and a layer of inorganic filler in the spaces. The thickness of the layer of inorganic filler is the same as the thickness of the electrode structures.

Abstract: There is provided an anode for an organic electronic device.

Abstract: A method for the separation of multiple dies during semiconductor fabrication is described. On an upper surface of a semiconductor wafer containing multiple dies, metal layers are deposited everywhere except where a block of stop electroplating material exists. The stop electroplating material is obliterated, and a barrier layer is formed above the entire remaining structure. A sacrificial metal element is added above the barrier layer, and then the substrate is removed. After the semiconductor material between the individual dies is eradicated, any desired bonding pads and patterned circuitry are added to the semiconductor surface opposite the sacrificial metal element, a passivation layer is added to this surface, and then the sacrificial metal element is removed. Tape is added to the now exposed barrier layer, the passivation layer is removed, the resulting structure is flipped over, and the tape is expanded to separate the individual dies.

Abstract: This invention disclosed a method to strengthen structure and enhance sensitivity for CMOS-MEMS micro-machined devices which include micro-motion sensor, micro-actuator and RF switch. The steps of the said method contain defining deposited region by metal and passivation layer, forming a cavity for depositing metal structure by lithography process, depositing metal structure on the top metal layer of micromachined structure by Electroless plating, polishing process and etching process. The method aims at strengthening structures and minimizing CMOS-MEMS device size. Furthermore, this method can also be applied to inertia sensors such as accelerometer or gyroscope, which can enhance sensitivity and capacitive value, and deal with curl issues for suspended CMOS-MEMS devices.

Abstract: 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.

Abstract: As a semiconductor device, specifically, a pixel portion included in a semiconductor device is made to have higher precision and higher aperture ratio, it is required to form a smaller wiring in width. In the case of forming a wiring by using an ink-jet method, a dot spreads on a wiring formation surface, and it is difficult to narrow width of a wiring. In the present invention, a photocatalytic substance typified by TiO2 is formed on a wiring formation surface, and a wiring is formed by utilizing photocatalytic activity of the photocatalytic substance. According to the present invention, a narrower wiring, that is, a smaller wiring in width than a diameter of a dot formed by an ink-jet method can be formed.

Abstract: A method for manufacturing a semiconductor device includes forming a laminated structure of a plurality of metal films on a semiconductor substrate using an electroless plating method. The forming of the metal films includes: performing an electroless plating process including a reduction reaction using a first plating tank; and performing an electroless plating process by only a substitution reaction using a second plating tank. The electroless plating process including the reduction reaction that is performed using the first plating tank is performed in a shading environment, and the electroless plating process performed by only the substitution reaction using the second plating tank is performed in a non-shading environment.

Abstract: 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.

Abstract: A method, in a complementary metal oxide semiconductor fabrication process, of creating a layered housing containing a micro-electromechanical system device, the method comprising the steps of providing a cavity in at least one layer of the housing, the cavity being accessible through via holes in a layer of insulating material deposited thereon, and the layer of insulating material being covered by a thin film layer of conductive material. The method further comprises the step of hydrophobically treating at least a portion of the inner surface of the cavity. Finally the method comprises the steps of submerging the wafer in an electroplating solution and electroplating a conductive layer onto the thin film layer of conductive material such that the cavity remains free of electroplating solution.

Abstract: Protective caps residing at an interface between metal lines and dielectric diffusion barrier (or etch stop) layers are used to improve electromigration performance of interconnects. Protective caps are formed by depositing a source layer of dopant-generating material (e.g., material generating B, Al, Ti, etc.) over an exposed copper line, converting the upper portion of the source layer to a passivated layer (e.g., nitride or oxide) while allowing an unmodified portion of a dopant-generating source layer to remain in contact with copper, and, subsequently, allowing the dopant from the unmodified portion of source layer to controllably diffuse into and/or react with copper, thereby forming a thin protective cap within copper line. The cap may contain a solid solution or an alloy of copper with the dopant.

Abstract: A semiconductor device includes a metal carrier and a spacer element attached to the metal carrier. The semiconductor device includes a first sintered metal layer on the spacer element and a semiconductor chip on the first sintered metal layer.

Abstract: A method for forming a film pattern by disposing a functional liquid in a pattern forming region partitioned by a bank includes: disposing a first bank forming material to a substrate so as to form a first bank layer; and forming a second bank layer on the first bank layer, wherein the first bank forming material is an organic material while the second bank layer is made of a fluorine resin material covering the first bank layer.

Abstract: 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.

Abstract: The manufacturing method of the present invention includes steps of selectively forming a photocatalyst material or a material including an amino group by discharging a composition including the photocatalyst material or the material including an amino group; immersing the photocatalyst material or the material including an amino group in a solution including a plating catalyst material so as to adsorb or deposit the plating catalyst material onto the photocatalyst material or the material including an amino group; and immersing the plating catalyst material in a plating solution including a metal material so as to form a metal film on a surface of the photocatalyst material or the material including an amino group adsorbing or depositing the plating catalyst material, thereby manufacturing a semiconductor device. The pH of the solution including the plating catalyst material is adjusted in a range of 3 to 6.

Abstract: A method is provided for electroforming metal integrated circuit structures. The method comprises: forming an opening such as a via or line through an interlevel insulator, exposing a substrate surface; forming a base layer overlying the interlevel insulator and substrate surface; forming a strike layer overlying the base layer; forming a top layer overlying the strike layer; selectively etching to remove the top layer overlying the substrate surface, exposing a strike layer surface; and, electroforming a metal structure overlying the strike layer surface. The electroformed metal structure is deposited using an electroplating or electroless deposition process. Typically, the metal is Cu, Au, Ir, Ru, Rh, Pd, Os, Pt, or Ag. The base, strike, and top layers can be deposited using physical vapor deposition (PVD), evaporation, reactive sputtering, or metal organic chemical vapor deposition (MOCVD).

Abstract: A method is provided for manufacturing removable contact structures on the surface of a substrate to conduct electricity from a contact member to the surface during electroprocessing. The method comprises forming a conductive layer on the surface. A predetermined region of the conductive layer is selectively coated by a contact layer so that the contact member touches the contact layer as the electroprocessing is performed on the conductive layer.

Abstract: A method (and system) of reducing contact resistance on a silicon-on-insulator device, including controlling a silicide depth in a source-drain region of the device.

Abstract: A semiconductor electroplating process deposits copper into the through silicon via hole to completely fill the through silicon via in a substantially void free is disclosed. The through silicon via may be more than about 3 micrometers in diameter and more that about 20 micrometers deep. Low copper concentration and high acidity electroplating solution is used for deposition copper into the through silicon vias.

Abstract: A method for fabricating a semiconductor device, includes forming a first dielectric film above a substrate, forming an opening in the first dielectric film, forming a catalytic characteristic film using at least one of a metal having catalytic characteristics and a conductive oxide having catalytic characteristics as its material on sidewalls and at a bottom of the opening, depositing a conductive material film using a conductive material in the opening in which the catalytic characteristic film is formed on the sidewalls and at the bottom, removing the catalytic characteristic film formed on the sidewalls of the opening, and forming a second dielectric film above the first dielectric film and the conductive material film after the removing.

Abstract: A method for forming a variable thickness Cu seed layer on a substrate for a subsequent Cu electrochemical plating process, where the Cu seed layer thickness profile improves uniformity of the electroplated Cu layer compared to when using a constant thickness Cu seed layer. The method includes depositing a Ru metal layer on the substrate, depositing a variable thickness Cu seed layer on the Ru metal layer by a physical vapor deposition process, whereby the variable thickness Cu seed layer is deposited with a Cu thickness at the edge of the substrate that is less than a Cu thickness at the center of the substrate, and plating bulk Cu onto the variable thickness Cu seed layer. The Ru metal layer may be a variable thickness Ru metal layer, or alternately, the Ru metal layer may have a substantially uniform Ru metal thickness across the substrate.

Abstract: A process for depositing a thin film material on a substrate is disclosed, comprising simultaneously directing a series of gas flows from the output face of a delivery head of a thin film deposition system toward the surface of a substrate, and wherein the series of gas flows comprises at least a first reactive gaseous material, an inert purge gas, and a second reactive gaseous material, wherein the first reactive gaseous material is capable of reacting with a substrate surface treated with the second reactive gaseous material. A system capable of carrying out such a process is also disclosed.

Abstract: A method producing conductive rods localized on conductive blocks of an electronic component.

Abstract: The invention provides a manufacturing method of a circular thin film transistor of which shape is more controlled than the conventional case, while simplifying the steps and reducing the manufacturing time and cost by forming a circular thin film transistor by a maskless process such as a droplet discharge method. In the invention, a circular thin film transistor having a circular electrode is formed by stacking concentric circular thin films over a substrate by a maskless process such as a droplet discharge method. Moreover, a circular thin film transistor having a circular semiconductor layer may be formed by stacking concentric circular thin films over a substrate by a maskless process such as a droplet discharge method.

Abstract: As a semiconductor device, specifically, a pixel portion included in a semiconductor device is made to have higher precision and higher aperture ratio, it is required to form a smaller wiring in width. In the case of forming a wiring by using an ink-jet method, a dot spreads on a wiring formation surface, and it is difficult to narrow width of a wiring. In the present invention, a photocatalytic substance typified by TiO2 is formed on a wing formation surface, and a wiring is formed by utilizing photocatalytic activity of the photocatalytic substance. According to the present invention, a narrower wiring, that is, a smaller wiring in width than a diameter of a dot formed by an ink-jet method can be formed.

Abstract: A metallic film 43 that becomes the matrix of pad 32 is formed on semiconductor substrate 41. Next, through hole 31 is formed in the semiconductor substrate 41 facing the metallic film 43 at the portion corresponding to an area where the pad 32 is formed. Thereafter, penetration electrode 17 is formed in through hole 31. Next, penetration portion 49 to expose the side of the penetration electrode 17 is formed in the semiconductor substrate 41. Next, an insulative member 16 is formed to be filled up in at least the penetration portion 49. After that, the pad 32 is formed by patterning the metallic film 43.

Abstract: A method is provided for forming silicon oxide layers during the processing of semiconductor devices by applying a SOG layer including polysilazane to a substrate and then substantially converting the SOG layer to a silicon oxide layer using an oxidant solution. The oxidant solution may include one or more oxidants including, for example, ozone, peroxides, permanganates, hypochlorites, chlorites, chlorates, perchlorates, hypobromites, bromites, bromates, hypoiodites, iodites, iodates and strong acids.

Abstract: Methods and apparatuses for fabricating three-dimensional integrated circuits having through hole vias are provided. One aspect of the present invention is a method of gapfill for through hole vias for three-dimensional integrated circuits. The method comprises providing a semiconductor wafer having a plurality of holes for through hole vias and depositing a conformal metal layer to partially fill the holes to leave open voids. The method also includes purging the voids and cleaning the surface of the voids and using a dry deposition process to fill or close the voids. Another aspect of the present invention is an electronic device structure for a three-dimensional integrated circuit.

Abstract: A method for fabricating multiple metal layers includes the following steps. An electronic component is provided with multiple contact points. A first metal layer is deposited over said electronic component. A first mask layer is deposited over said first metal layer. A second metal layer is deposited over said first metal layer exposed by an opening in said first mask layer. Said first mask layer is removed. A second mask layer is deposited over said second metal layer. A third metal layer is deposited over said second metal layer exposed by an opening in said second mask layer. Said second mask layer is removed. Said first metal layer not covered by said second metal layer is removed.

Abstract: A method for the separation of multiple dies during semiconductor fabrication is described. On an upper surface of a semiconductor wafer containing multiple dies, metal layers are deposited everywhere except where a block of stop electroplating material exists. The stop electroplating material is obliterated, and a barrier layer is formed above the entire remaining structure. A sacrificial metal element is added above the barrier layer, and then the substrate is removed. After the semiconductor material between the individual dies is eradicated, any desired bonding pads and patterned circuitry are added to the semiconductor surface opposite the sacrificial metal element, a passivation layer is added to this surface, and then the sacrificial metal element is removed. Tape is added to the now exposed barrier layer, the passivation layer is removed, the resulting structure is flipped over, and the tape is expanded to separate the individual dies.

Abstract: A method is provided for manufacturing removable contact structures on the surface of a substrate to conduct electricity from a contact member to the surface during electroprocessing. The method comprises forming a conductive layer on the surface. A predetermined region of the conductive layer is selectively coated by a contact layer so that the contact member touches the contact layer as the electroprocessing is performed on the conductive layer.

Abstract: By forming an activation/nucleation layer selectively at a bottom of an opening, efficient electroless deposition techniques may be used for forming contacts, vias and trenches of advanced semiconductor devices. By selectively providing the activation material, a self-aligned bottom-to-top fill behavior may be obtained.

Abstract: The present invention provides a method for manufacturing a wiring and a method for manufacturing a semiconductor device, which do not require a photolithography step in connecting a pattern of an upper layer and a pattern of a lower layer. According to the present invention, a composition including a conductive material is discharged locally and an electric conductor to function as a pillar is formed on a first pattern over a substrate, an insulator is formed to cover the electric conductor, the insulator is etched to expose a top surface of the electric conductor, and a second pattern is formed on the top surface of electric conductor that is exposed.

Abstract: As a semiconductor device, specifically, a pixel portion included in a semiconductor device is made to have higher precision and higher aperture ratio, it is required to form a smaller wiring in width. In the case of forming a wiring by using an ink-jet method, a dot spreads on a wiring formation surface, and it is difficult to narrow width of a wiring. In the present invention, a photocatalytic substance typified by TiO2 is formed on a wiring formation surface, and a wiring is formed by utilizing photocatalytic activity of the photocatalytic substance. According to the present invention, a narrower wiring, that is, a smaller wiring in width than a diameter of a dot formed by an ink-jet method can be formed.

Abstract: A method is provided for electroforming metal integrated circuit structures. The method comprises: forming an opening such as a via or line through an interlevel insulator, exposing a substrate surface; forming a base layer overlying the interlevel insulator and substrate surface; forming a strike layer overlying the base layer; forming a top layer overlying the strike layer; selectively etching to remove the top layer overlying the substrate surface, exposing a strike layer surface; and, electroforming a metal structure overlying the strike layer surface. The electroformed metal structure is deposited using an electroplating or electroless deposition process. Typically, the metal is Cu, Au, Ir, Ru, Rh, Pd, Os, Pt, or Ag. The base, strike, and top layers can be deposited using physical vapor deposition (PVD), evaporation, reactive sputtering, or metal organic chemical vapor deposition (MOCVD).

Abstract: It is required that a line width of a wiring is prevented from being wider to be miniaturized when the wiring or the like is formed by a dropping method typified by an ink-jetting method. The invention provides a method for narrowing (miniaturizing) a line width according to a method different from a conventional method. One feature of the invention is that a plasma treatment is performed before forming a wiring or the like by a dropping method typified by an ink-jetting method. As the result of the plasma treatment, a surface for forming a conductive film is modified to be liquid-repellent. Consequently, a wiring or the like formed by a dropping method can be miniaturized.