Abstract: A two-step via cleaning process which removes metal polymer and oxide polymer residues from a via with substantially no damage to the via or underlying structures on a semiconductor substrate. The via is formed through a dielectric layer and a barrier layer which are disposed over a metal-containing trace, pad, or other such circuitry, wherein the metal-containing trace, pad, or other circuitry is disposed on a semiconductor substrate. When such a via is formed, the sidewalls of the via are coated with a residue layer. The residue layer generally has a distinct oxide polymer component and a distinct metal polymer component. The two-step cleaning process comprises first subjecting the residue layer to a nitric acid dip which removes the metal polymer component to expose the oxide polymer component. The oxide polymer component is then subjected to a phosphoric acid dip which removes the oxide polymer component.

Abstract: An anti-reflection coating 5 used at time of forming a first contact hole 6 is interposed between a first insulating layer 4 and a second insulating layer 80, and the anti-reflection coating 5 is served as an etching prevention film for the first insulating layer 4 at time of forming a second contact hole 9 in the second insulating layer 80, whereby an electrical short between a conductive plug and an electrode layer is prevented; an electrical connection between upper and lower conductive plugs is stabilized; and a semiconductor device having a highly reliable contact structure, in which multi-layer conductive plugs are included, is obtainable.

Abstract: A semiconductor device, which is comprised of a copper wiring layer which is formed above a semiconductor substrate, a pad electrode layer which conducts electrically to the copper wiring layer and has an alloy, which contains copper and a metal whose oxidation tendency is higher than copper, formed to extend to the bottom surface, and an insulating protective film which has an opening extended to the pad electrode layer, is provided.

Abstract: A method and structure for protecting a flowable oxide insulator in a semiconductor by oxidizing sidewalls of the FOX insulator, optionally nitridizing the oxidized FOX sidewalls, and then covering all surfaces of a trough or plurality of troughs in the FOX insulator, including the sidewalls, with a conductive secondary protective layer. In a multiple layer damascene structure, the surface of the FOX insulator is also oxidized, an additional oxide layer is deposited thereon, and a nitride layer deposited on the oxide layer. Then steps are repeated to obtain a comparable damascene structure. The materials can vary and each damascene layer may be either a single damascene or a dual damascene layer.

Abstract: A semiconductor device has a semiconductor substrate having a main surface including a first region and a second region, and an interlayer dielectric film formed over the first region and the second region. A bonding pad, a power source line, a test pattern or the like is formed in the first region, and a logic circuit, an analog circuit, a memory circuit or the like is formed in the second region. The interlayer dielectric film has a maximum thickness over the first region, and a thickness that is about 90-50% of the maximum thickness over the second region. The interlayer dielectric film defines a first through hole formed over the first region and a second through hole formed over the second region. An aperture area of the first through hole is greater than that of the second through hole. As a result, the range of the focus margin for forming the first through hole covers the range of the focus margin for forming the second through hole.

Abstract: Disclosed is a technique capable of enhancing the degree of freedom in the layout of a rerouting layer in a wafer level CSP in which defect repairing is performed by cutting a fuse. More specifically, after the defect repairing is performed by irradiating a laser beam to a fuse, an organic passivation layer (photo-sensitive polyimide layer) is filled in a fuse opening. Thereafter, a rerouting layer, a bump land, an uppermost wiring layer, and a solder bump are formed on the organic passivation layer. In the following steps of the defect repairing, the baking process to cure an elastomer layer and the uppermost protection layer is conducted at a temperature below 260° C. in order to prevent the variance of the refresh times of memory cells.

Abstract: A typical air bridge is an aluminum conductor suspended across an air-filled cavity to connect two components of an integrated circuit, two transistors for example. The air-filled cavity has a low dielectric constant which reduces cross-talk between neighboring conductors and improves speed and efficiency of the integrated circuit. However, current air bridges must be kept short because typical aluminum conductors sag too much. Accordingly, one embodiment of the invention forms air-bridge conductors from an aluminum-beryllium alloy, which enhances stiffness and ultimately provides a 40-percent improvement in air-bridge lengths.

Abstract: A low resistance path extends from a first region of a semiconductor substrate to a second region thereof. The low resistance path is produced by depositing a metal such as aluminum on the surface of the substrate and then directing a laser beam onto the metal causing the metal and a portion of the substrate beneath the metal to melt forming an alloy of the metal and the substrate material.

Abstract: Surface applied passive devices for use on electronic circuit boards are formed by applying layers of conductive, insulating, and other material to a thin polymer film carrier. The surface applied passives are thin enough to fit underneath standard integrated circuit packages in order to conserve space on the circuit board. Resistors, capacitors, inductors and other passive circuits may be formed on thin polymer films, less than 8 mils thick. This significantly aids in conserving space on an electronic circuit board.

Abstract: Titanium aluminum nitrogen (“Ti—Al—N”) is deposited onto a semiconductor substrate area to serve as an antireflective coating. For wiring line fabrication processes, the Ti—Al—N layer serves as a cap layer which prevents unwanted reflection of photolithography light (i.e., photons) during fabrication. For field emission display devices (FEDs), the Ti—Al—N layer prevents light originating at the display screen anode from penetrating transistor junctions that would hinder device operation. For the wiring line embodiment an aluminum conductive layer and a titanium-aluminum underlayer are formed beneath the antireflective cap layer. The Ti—Al underlayer reduces the shrinkage which occurs in the aluminum conductive layer during heat treatment.

Abstract: In order to solve the aforementioned problems, the present invention provides a semiconductor device having a multilayer interconnection structure, wherein an upper interconnection comprises a first metal layer composed of an aluminum alloy, which is formed over a lower interconnection, and a second metal layer formed over the first metal layer and composed of an aluminum alloy formed as a film at a temperature higher than that for the first metal layer. Another invention provides a semiconductor device having a multilayer interconnection structure, wherein a metal region composed of a metal different from an aluminum alloy is formed in a portion spaced by a predetermined distance in an extending direction of an upper interconnection from an end of a via hole defined in the upper interconnection composed of the aluminum alloy, which is electrically connected to a lower interconnection through the via hole.

Abstract: A power semiconductor module has a circuit assembly body, which includes a metal base, a ceramic substrate, and a power semiconductor chip, and is combined with a package having terminals formed integrally. The ceramic substrate of the module has a structure such that an upper circuit plate and a lower plate are joined to both sides of a ceramic plate, respectively, and the metal base and the ceramic substrate are fixed to one another using solder, thereby improving reliability and lengthening a life of a power semiconductor module by optimizing a ceramic substrate and a metal base thereof, the dimensions thereof, and material and method used for a join formed between the ceramic substrate and metal base.

Abstract: The electromigration characteristics of patterned metal features, such as metal lines, in semiconductor devices is improved by applying a conductive layer to substantially surround and encapsulate the patterned metal features. A portion of the conductive layer may be removed to form conductive sidewall spacers on the side surfaces of the patterned metal features. In an embodiment of the invention, the conductive layer comprises a first layer of titanium and a second layer of titanium-nitride thereon.

Abstract: A method of making a microelectronic device providing a base substrate having a bond pad, a first passivation layer overlying the base substrate and a portion of the bond pad, and a second passivation layer overlying the first passivation layer; forming a first sacrificial layer over the second passivation layer, wherein the first sacrificial layer includes an opening therethrough; etching the exposed portion of the second passivation layer to provide a recess therein; trimming a portion of the first sacrificial layer to enlarge the opening; etching the exposed portion of the second passivation layer to provide an enlarged recess and a first riser, a second tread, a second riser and a second tread; removing the first sacrificial layer; depositing a redistribution layer into the enlarged recess in the second passivation layer and over the first riser, first tread, second riser, and second tread.

Abstract: A semiconductor device comprised of a substantially conformal layer of titanium silicon oxide deposited on a semiconductor substrate. The layer of titanium silicon oxide is substantially free of chlorine related impurities. The layer of titanium silicon oxide may have a ratio of silicon to titanium from about 0.1 to about 1.9. The layer of titanium silicon oxide may have a dielectric constant from about 10 to about 30, and a thickness from about 15 angstroms to about 500 angstroms.

Abstract: A method for manufacturing a semiconductor device having on a silicon substrate semiconductor elements and aluminum (Al) alloy wiring leads as electrically connected thereto is disclosed. The method includes the steps of forming on the silicon substrate an Al alloy layer containing therein copper (Cu), and forming on the Al alloy layer a titanium nitride (TiN) film with enhanced chemical reactivity by using sputtering techniques while applying thereto a DC power of 5.5 W/cm2 or less. Fabrication of such reactivity-rich TiN film on the Al alloy layer results in a reaction layer of Al and Ti being subdivided into several spaced-apart segments. In this case, the reaction layer hardly serves as any diffusion path; thus, it becomes possible to prevent Cu as contained in the Al alloy layer from attempting to outdiffuse with the reaction layer being as its diffusion path.

Abstract: An integrated circuit metallization structure using a titanium/aluminum alloy, and a method to generate such a structure, provide reduced leakage current by allowing mobile impurities such as water, oxygen, and hydrogen to passivate structural defects in the silicon layer of the IC. The titanium layer of the structure is at least partially alloyed with the aluminum layer, thereby restricting the ability of the titanium to getter the mobile impurities within the various layers of the IC. Despite the alloying of the titanium and aluminum, the metallization structure exhibits the superior contact resistance and electromigration properties associated with titanium.

Abstract: A multi layered copper bond pad for a semiconductor die which inhibits formation of copper oxide is disclosed. A small dose of titanium is implanted in the copper surface. The implanted titanium layer suppresses the copper oxide growth in the copper bond pad by controlling the concentration of vacancies available to the copper ion transport. An interconnect structure such as a wire bond or a solder ball may be attached to the copper-boron layer to connect the semiconductor die to a lead frame or circuit support structure. In another embodiment, a titanium-aluminum passivation layer for copper surfaces is also disclosed. The titanium-aluminum layer is annealed to form a titanium-aluminum-copper alloy. The anneal may be done in a nitrogen environment to form a titanium-aluminum-copper-nitrogen alloy.

Abstract: A metal interconnect structure and method of making the same implants ions of an alloy elements into a copper line through a via. Then ion implantation of the alloy elements in the copper line through the via provides improved electromigration properties at the copper line at a critical electromigration failure site, without attempting to provide alloy elements throughout the entire copper line.

Abstract: First, a conductive material of aluminum-based material is deposited and patterned to form a gate wire including a gate line, a gate pad, and a gate electrode. A gate insulating layer is formed by depositing nitride silicon in the range of more than 300° C. for 5 minutes, and a semiconductor layer an ohmic contact layer are sequentially formed. Next, a conductor layer of a metal such as Cr is deposited and patterned to form a data wire include a data line intersecting the gate line, a source electrode, a drain electrode and a data pad. Then, a passivation layer is deposited and patterned to form contact holes exposing the drain electrode, the gate pad and the data pad. Next, indium zinc oxide is deposited and patterned to form a pixel electrode, a redundant gate pad and a redundant data pad respectively connected to the drain electrode, the gate pad and the data pad.

Abstract: A semiconductor device with satisfactory bonding ability of a plasma SiOF oxide layer on a wiring and satisfactory burying ability for burying wiring space portions. The semiconductor substrate, forming an anti-reflection layer of a refractory metal or compound thereof, on the metal layer, and forming an insulation layer on the anti-reflection layer. There after, the insulation layer is patterned and a wiring is formed by etching the anti-reflection layer and the metal layer while taking the patterned insulation layer as a mask and leaving the anti-reflection layer and the insulation layer on the wiring. Subsequently, the patterned wiring is buried with an SiOF layer as an Si oxide layer containing fluorine, together with the anti-reflection layer and the insulation layer on the upper surface thereby.

Abstract: In a semiconductor device using fill shape patterns incorporated into wiring levels to increase the planarity of the wiring levels, the fill shapes are aligned from one wiring level to another wiring level to provide lines of sight to lower wiring levels for visual inspection. Also, in accordance with the invention, selected aligned fill shapes are interconnected with vias to form conductive stacks for contacting lower wiring level conductive wires from upper wiring levels in order to perform electrical test probing/diagnostics.

Abstract: An interconnect line that is enclosed within electrically conductive material is disclosed. The interconnect line, which is useful for electrically connecting devices in an integrated circuit, is defined by an aluminum layer having a bottom surface covered by a titanium layer, a top surface covered by a titanium layer, and opposing side surfaces covered by discrete titanium layers. The encapsulation of the aluminum layer within the titanium layers substantially precludes void formation within the aluminum layer. The interconnect line also may be upon a contact plug that is in electrical communication with an active area in an underlying semiconductor substrate.

Abstract: The invention describes an assembly provided with a component and a substrate (7). The component and the substrate (7) are electrically interconnected by means of connecting structures (6, 8). The first connecting structure (6) of the component comprises aluminum, which simplifies the manufacture of the assembly.

Abstract: The present invention relates to a conductive line on an integrated circuit. The integrated circuit includes an insulating layer in which is formed several grooves of predetermined width. The conductive line includes a first interconnection layer having a first thickness and a second interconnection layer having a second thickness. The predetermined width is greater than twice the greatest of the two thicknesses, and smaller than twice the sum of the thicknesses.

Abstract: A TRIAC which is one species of chip-type semiconductors includes an element body made of silicon, electrodes provided on one face of the element body, a molybdenum plate provided on one of the electrodes by an alloy plate made of aluminum and silicon, a molybdenum plate provided on the other face of the element body by a similar alloy plate, and nickel layers provided on connection faces of the molybdenum plates to outer electrode plates, so that the electrode and molybdenum plate are firmly connected without conventional high-temperature solder which includes a great amount of lead, and that the alloy plate never melt even when newly developed low-temperature institute is employed, and that the operation of the molybdenum plates is sufficiently realized.

Abstract: An electronic circuit formed on an insulating substrate and having thin-film transistors (TFTs) comprising semiconductor layers. The thickness of the semiconductor layer is less than 1500 Å, e.g., between 100 and 750 Å. A first layer consisting mainly of titanium and nitrogen is formed on the semiconductor layer. A second layer consisting of aluminum is formed on top of the first layer. The first and second layers are patterned into conductive interconnects. The bottom surface of the second layer is substantially totally in intimate contact with the first layer. The interconnects have good contacts with the semiconductor layer.

Abstract: A low-k dielectric metal conductor interconnect structure having no micro-trenches present therein and a method of forming such a structure are provided. Specifically, the above structure is achieved by providing an interconnect structure which includes at least a multilayer of dielectric materials which are applied sequentially in a single spin apply tool and then cured in a single step and a plurality of patterned metal conductors within the multilayer of spun-on dielectrics. The control over the conductor resistance is obtained using a buried etch stop layer having a second atomic composition located between the line and via dielectric layers of porous low-k dielectrics having a first atomic composition. The inventive interconnect structure also includes a hard mask which assists in forming the interconnect structure of the dual damascene-type.

Abstract: Methods of forming a metal interconnects include forming an electrically insulating layer having a contact hole therein, on a substrate. A step is also performed to form an electrically conductive seed layer. The seed layer extends on a sidewall of the contact hole and on a portion of an upper surface of the electrically insulating layer extending adjacent the contact hole. The seed layer is sufficiently thick along an upper portion of the sidewall and sufficiently thin along a lower portion of the sidewall that an upper portion of the contact hole is partially constricted by the seed layer and a constricted contact hole is thereby defined. An anti-nucleation layer is deposited on a portion of the seed layer that extends outside the constricted contact hole. The constricted contact hole is used as a mask to inhibit deposition of the anti-nucleation layer adjacent a bottom of the constricted contact hole.

Abstract: A corrosion-resistant conductive layer (TiW layer) formed of a corrosion-resistant material is formed to extend from a bonding pad portion to an interconnection portion of a light receiving element. A semiconductor laser device according to the present invention includes the light receiving element.

Abstract: An interconnection wiring structure in an integrated circuit chip designed to eliminate electromigration. The structure includes segments of aluminum interspersed with segments of refractory metal, wherein each aluminum segment is followed by a segment of refractory metal. The aluminum and refractory metal segments are aligned with respect to each other to ensure electrical continuity and to force the electrical current to sequentially cross the aluminum and the refractory metal segments. The above structure can be advantageously enhanced by adding an underlayer, an overlayer or both, all of which are made of refractory metal. The interconnection wire structure described above can be expanded to include vias or studs linking interconnection lines placed at different levels of the IC chip.

Abstract: A method of making a contact plug and a metallization line structure is disclosed in which a substrate is provided with at least one contact hole within an insulation layer situated on a semiconductor substrate of a semiconductor wafer. A first metal layer is deposited upon the semiconductor wafer within the contact hole. A planarizing step isolates the first metal layer within the insulation layer in the form of a contact plug within the contact hole. A second metal layer is then deposited upon the semiconductor wafer over and upon the contact plug. Metallization lines are patterned and etched from the second metal layer. The contact hole may also be lined with a refractory metal nitride layer, with a refractory metal silicide interface being formed at the bottom of the contact hole as an interface between the contact plug and a silicon layer on the semiconductor substrate.

Abstract: Aluminum-containing films having an oxygen content within the films. The aluminum-containing film is formed by introducing hydrogen gas along with argon gas into a sputter deposition vacuum chamber during the sputter deposition of aluminum or aluminum alloys onto a semiconductor substrate. The aluminum-containing film so formed is hillock-free and has low resistivity, relatively low roughness compared to pure aluminum, good mechanical strength, and low residual stress.

Abstract: A microelectronic substrate having a plurality of alternating substantially planar layers of dielectric material and conductive material, and further having a first surface and a second surface, wherein the dielectric material and the conductive material layers extend substantially perpendicularly between the first and second surfaces.

Abstract: Semiconductor films include insulating films including contact holes in semiconductor substrates, capacitors comprising lower electrodes formed on conductive material films in the contact holes, high dielectric films formed on the lower electrodes and upper electrodes formed on the high dielectric films, and barrier metal layers positioned between conductive materials in the contact holes and the lower electrodes, the barrier metal layers including metal layers formed in A-B-N structures in which a plurality of atomic layers are stacked by alternatively depositing reactive metal (A), an amorphous combination element (B) for preventing crystallization of the reactive metal (A) and nitrogen (N). The composition ratios of the barrier metal layers are determined by the number of depositions of the atomic layers.

Abstract: A lower metal plate having a strip-like opening is used in a bond pad structure having metal plugs coupling the lower metal plate to an upper metal plate. A volume of relatively rigid material filling a volume above the strip-like opening transfers stress from the upper metal plate, through the strip-like opening, and to a foundation layer upon which the lower metal plate is disposed. The bond pad structure can be fabricated using the same semiconductor processing steps used to fabricate amorphous silicon antifuse structures having metal plugs.

Abstract: In the invention an electrically isolated copper interconnect structural interface is provided involving a single, about 50-300 A thick, alloy capping layer, that controls diffusion and electromigration of the interconnection components and reduces the overall effective dielectric constant of the interconnect; the capping layer being surrounded by a material referred to in the art as hard mask material that can provide a resist for subsequent reactive ion etching operations, and there is also provided the interdependent process steps involving electroless deposition in the fabrication of the structural interface. The single layer alloy metal barrier in the invention is an alloy of the general type A—X—Y, where A is a metal taken from the group of cobalt (Co) and nickel (Ni), X is a member taken from the group of tungsten (W), tin (Sn), and silicon (Si), and Y is a member taken from the group of phosphorous (P) and boron (B); having a thickness in the range of 50 to 300 Angstroms.

Abstract: A multi-layer film for a thin film structure, a capacitor using the multi-layer film and methods for fabricating the multi-layer film and the capacitor, the multi-layer film including a composition transition layer between a lower material layer and an upper material layer respectively formed of different elements whose interaction parameters are different from each other, the composition transition layer containing both elements of the lower and upper material layers, the concentration of the composition transition layer gradually varying from the portion of the composition transition layer contacting with the lower material layer to the portion of the composition transition layer contacting with the upper material layer such that the concentration of the element of the upper material layer is relatively large in its portion adjacent to the upper material layer, each of the lower and upper material layers being formed of an oxide or nitride material of aluminum, silicon, zirconium, cerium, titanium, yttrium,

Abstract: In one aspect, the invention includes a semiconductor device comprising: a) an electrically insulative layer over a substrate; b) an opening within the electrically insulative layer, the opening having a periphery defined at least in part by a bottom surface and a sidewall surface; c) a first layer comprising TiN within the opening, the first layer being over the bottom surface and along the sidewall surface; d) a second layer comprising elemental Ti over the electrically insulative layer but substantially not within the opening, the second layer having a thickness of less than 75Å along the sidewall surface and over the bottom surface; and e) an aluminum-comprising layer within the opening and over the second layer.

Abstract: In a method for manufacturing a semiconductor device in which wiring layers are formed by a damascene method, certain embodiment relate to a manufacturing methods and semiconductor devices, in which a bonding pad section having a multiple-layered structure can be formed by a simple method without increasing the number of process steps.

Abstract: In extremely minute copper wiring the width or the thickness of which is equal to or shorter than approximately the double length of the mean free path of a copper atom, a value of the resistance may be larger, compared with aluminum wiring of the same extent and it is difficult to realize wiring having small resistance. To solve such a problem, aluminum wiring is used for wiring having form in which the respective resistivities &rgr; of both wirings have the relation of &rgr;Al<&rgr;Cu and copper wiring is used for wiring having form in which the respective resistivities &rgr; of both wirings have the relation of &rgr;Al≧&rgr;Cu. As a result, a semiconductor device which has small resistance, transmits a signal at high speed and is provided with a multilayer wiring layer can be realized.

Abstract: A pin standing resin substrate 311 comprises a resin substrate 313 and many pins 301 soldered (HD) to a pin-pad 317A, the resin substrate comprising such as a resin and having a pin-pad 317AP whose diameter of a portion exposed in a main surface 313A is 0.9 to 1.1 mm. The kovar-made pin 301 is previously heat-treated at 700° C., whereby Vickers hardness is made Hv=around 150, and the pin has a rod-like portion 301A of a diameter being 0.3 mm and an enlarged diameter portion 301B shaped in disk being 0.60 to 0.70 mm and thickness being 0.15 to 0.20 mm, the enlarged diameter portion being formed at one end of the rod-like portion 301A. This enlarged diameter portion 301B is soldered to the pin-pad.

Abstract: An integrated circuit and manufacturing method therefor is provided having a semiconductor substrate with a semiconductor device. A device dielectric layer is formed on the semiconductor substrate and a channel dielectric layer on the device dielectric layer has an opening formed therein. A barrier layer lines the channel opening and a conductor core fills the opening over the barrier layer. A seedless barrier layer lines the opening, and a conductor core fills the opening over the seedless barrier layer. The barrier layer is deposited in the opening and contains atomic layers of barrier material which bonds to the dielectric layer, an intermediate material which bonds to the barrier material layer and to the conductor core, and a conductor core material which bonds to the intermediate material. The conductor core bonds to the conductor core material.

Abstract: A method for making an integrated circuit device includes forming at least one interconnect structure adjacent a substrate by forming at least one barrier layer, forming a doped copper seed layer on the at least one barrier layer, and forming a copper layer on the doped copper seed layer. The method may further include annealing the integrated circuit device after forming the copper layer to diffuse the dopant from the doped copper seed layer into grain boundaries of the copper layer. The doped copper seed layer may include at least one of calcium, cadmium, zinc, neodymium, tellurium, and ytterbium as a dopant to provide the enhanced electromigration resistance. Forming the copper layer may comprise plating the copper layer. In addition, forming the copper layer may comprise forming the copper layer to include at least one of calcium, cadmium, zinc, neodymium, tellurium, and ytterbium as a dopant.

Abstract: A semiconductor device having a contact layer and a diffusion barrier layer is fabricated by preparing a semiconductor substrate, forming a layer of titanium/aluminum alloy on the surface of the substrate, and then heating the resultant structure in a nitrogen ambient to form a contact layer of titanium silicide interposed between the substrate and a diffusion barrier layer consisting of titanium/aluminum/nitride.

Abstract: A semiconductor device manufacturing method of the this invention having the step of forming an interlayer insulating film on a semiconductor substrate, the step of making interconnection groove in the interlayer insulating film, the step of filling the inside of the interconnection groove with a conductive film which is made of a first substance and is thicker than the depth of the interconnection groove, the step of thermally stabilizing the size of crystal grains in an Al film either at the same time or after the Al film has been formed, the step of forming a Cu film on the Al film, the step of selectively forming &thgr; phase layers in a crystal grain boundary of the Al film by causing Cu to selectively diffuse into the crystal grain boundary of Al film and of allowing the &thgr; phase layers to divide the Al film in the interconnection groove into fine Al interconnections shorter than the Blech critical length, and the step of removing the Al film and Cu film outside the interconnection groove.

Abstract: There is provided a semiconductor device having a wiring structure which reduces possibility of a short circuit, and method of making the device. Besides, there is provided a semiconductor device having high reliability. Further, there is provided a semiconductor device having high yield. A wiring line is formed at one main surface side of a semiconductor substrate, and has a laminate structure of an adjacent conductor layer and a main wiring layer. The main wiring layer contains an added element to prevent migration. The adjacent conductor layer is formed of a material for preventing a main constituent element and the added element of the main wiring layer from diffusing into the substrate beneath the adjacent conductor layer, and the concentration of the added element at a location close to an interface between the adjacent conductor layer and the main wiring layer is low compared to the concentration of the added element in the main wiring layer spaced from the adjacent conductor layer.

Abstract: A method for making a semiconductor integrated circuit device comprises the steps of: (a) depositing a first underlying film made of titanium nitride, on an insulating film having a plurality of through-holes; (b) depositing a tungsten film on the first underlying film, and etching the tungsten film back by means of a fluorine-containing plasma thereby leaving the tungsten film only in the connection holes; (c) sputter etching the surface of the first underlying film to remove the fluorine from the surface of the first underlying film; and (d) forming an aluminum film on the first underlying film. The semiconductor integrated circuit device obtained by the method is also described.

Abstract: The present invention concerns the field of microstructures and in particular microstructures made via CMOS technology on semiconductor substrates intended to undergo micro-machining by wet chemical etching, in particular by a KOH etchant. According to the present invention, protection against the KOH reactive agent is provided to such a structure by the deposition of a metal film (40, 41, 43) including at least on external gold layer (43) on the surface of the structure. This metal film (40, 41, 43) advantageously allows the use of mechanical protective equipment to be omitted and thus allows the wafers to be processed in batches. The present invention also proves perfectly compatible with a standard gold bumping process.

Abstract: A multi-layer conductor system including: a base layer having an electrically insulative top portion including alumina; an electrically conductive intermediate layer formed on the top portion of the base layer; and an electrically conductive top layer formed on the intermediate layer; wherein the intermediate layer includes alumina and a precious metal alloy consisting of silver and a precious metal other than silver; wherein the top layer comprises a precious metal selected from the group consisting of silver and a silver alloy such that the difference between the percentage weight of silver in the precious metal of the top layer and the percentage weight of silver in the precious metal alloy of the intermediate layer is limited to thereby provide advantages in use.