Abstract: A semiconductor device includes a semiconductor substrate including a bump electrode, a first insulating layer formed on the semiconductor substrate and arranged to a lateral direction of the bump electrode, a first wiring layer formed on the first insulating layer and connected to the bump electrode, a second insulating layer formed on the first wiring layer, a via hole formed in the second insulating layer, and reaching the first wiring layer, a second wiring layer formed on the second insulating layer and connected to the first wiring layer via a via conductor formed in the via hole, and an external connection terminal connected to the second wiring layer, wherein an elastic modulus of the second insulating layer is set lower than an elastic modulus of the first insulating layer.

Abstract: Some embodiments include constructions which have platinum-containing structures. In some embodiments, the constructions may have a planarized surface extending across the platinum-containing structures and across metal oxide. In some embodiments, the constructions may have a planarized surface extending across the platinum-containing structures, across a first material retaining the platinum-containing structures, and across metal oxide liners along sidewalls of the platinum-containing structures and directly between the platinum-containing structures and the first material. Some embodiments include methods of forming platinum-containing structures. In some embodiments, first material is formed across electrically conductive structures, and metal oxide is formed across the first material. Openings are formed to extend through the metal oxide and the first material to the electrically conductive structures. Platinum-containing material is formed within the openings and over the metal oxide.

Abstract: An improved system and method for assigning power and ground pins and single ended or differential signal pairs for a ball grid array semiconductor package. In certain embodiments, the system uses a hexagonal pattern where the grid may be represented by a multiplicity of nested hexagonal patterns.

Abstract: A metal interconnect structure and a method of manufacturing the metal interconnect structure. Manganese (Mn) is incorporated into a copper (Cu) interconnect structure in order to modify the microstructure to achieve bamboo-style grain boundaries in sub-90 nm technologies. Preferably, bamboo grains are separated at distances less than the “Blech” length so that copper (Cu) diffusion through grain boundaries is avoided. The added Mn also triggers the growth of Cu grains down to the bottom surface of the metal line so that a true bamboo microstructure reaching to the bottom surface is formed and the Cu diffusion mechanism along grain boundaries oriented along the length of the metal line is eliminated.

Abstract: There is provided a method of manufacturing a semiconductor device including: preparing a semiconductor substrate, forming a first insulating layer, a first redistribution layer, a second insulating layer, a second redistribution layer, and at least one of first processing, in which, after the first electrically conductive material is filled in the first opening to form a first via interconnect, the first redistribution layer is formed on the first insulating layer with the first electrically conductive material such that the first redistribution layer is electrically connected to the first via interconnect; or second processing, in which, after the second electrically conductive material is filled in the second opening to form a second via interconnect, the second redistribution layer is formed on the second insulating layer with the second electrically conductive material such that the second redistribution layer is electrically connected to the second via interconnect.

Abstract: To provide a highly reliable light-emitting device with less occurrence of cracks in a sealant bonding two facing substrates together. In a light-emitting device, a first substrate including a light-emitting unit, and a second substrate are bonded to each other with glass frit. A wiring in the area overlapping with a sealing material formed by melting and solidifying glass frit may be formed of a conductive material having a linear thermal expansion coefficient close to that of a substrate material. More specifically, the difference in the linear thermal expansion coefficient between the conductive material and the substrate material is 5 ppm/K or less at a temperature of 0° C. to 500° C.

Abstract: A method of manufacture of an integrated circuit packaging system includes: forming a peripheral interconnect having a bond finger and a contact pad with a trace in direct contact with the bond finger and the contact pad, the bond finger vertically offset from the contact pad; connecting an integrated circuit die and the bond finger; and forming a module encapsulation on the integrated circuit die, the bond finger and the trace exposed from the module encapsulation.

Abstract: According to one embodiment, a semiconductor device includes a first insulating layer provided in a first area and in a second area, a line-and-space-like second insulating layer formed on the first insulating layer provided in the first area, and a third insulating layer formed on the first insulating layer provided in the second area and which is substantially identical to the second insulating layer in height.

Abstract: A semiconductor arrangement includes a circuit carrier, a bonding wire and at least N half bridge circuits. N is an integer that amounts to at least 1. The circuit carrier includes a first metallization layer, a second metallization layer, an intermediate metallization layer arranged between the first metallization layer and the second metallization layer, a first insulation layer arranged between the intermediate metallization layer and the second metallization layer, and a second insulation layer arranged between the first metallization layer and the intermediate metallization layer. Each of the half bridge circuits includes a first circuit node, a second circuit node and a third circuit node, a controllable first semiconductor switch and a controllable second semiconductor switch.

Abstract: A semiconductor device having stacked semiconductor chips is provided wherein alignment of even thin semiconductor chips of a large warpage is easy and thus high assembling accuracy and high reliability are ensured. Semiconductor chips having hollow through-silicon via electrodes each formed with a tapered portion are melt-joined using solder balls each having a core of a material higher in melting point than solder. When melt-joining the semiconductor chips, the temperature is raised while imparting an urging load to stacked semiconductor chips, thereby correcting warpage of the semiconductor chips. In each chip-to-chip connection thus formed, if the connection is to prevent the occurrence of stress around the electrode due to the urging load, a solder ball having a core of a smaller diameter than in the other connections is used in the connection.

Abstract: A semiconductor device includes: a metal-containing compound layer on a semiconductor substrate; a dielectric film on the semiconductor substrate and the metal-containing compound layer; a contact hole penetrating through the dielectric film to reach the metal-containing compound layer; a contact plug in the contact hole. The semiconductor device further includes a manganese oxide layer extending between the contact plug and respective one of the dielectric film and the metal-containing compound layer.

Abstract: Embodiments of a method for fabricating integrated circuits are provided, as are embodiments of an integrated circuit. In one embodiment, the method includes the steps of depositing an interlayer dielectric (“ILD”) layer over a semiconductor device, depositing a barrier polish stop layer over the ILD layer, and patterning at least the barrier polish stop layer and the ILD layer to create a plurality of etch features therein. Copper is plated over the barrier polish stop layer and into the plurality of etch features to produce a copper overburden overlying the barrier polish stop layer and a plurality of conductive interconnect features in the ILD layer and barrier polish stop layer. The integrated circuit is polished to remove the copper overburden and expose the barrier polish stop layer.

Abstract: A semiconductor integrated circuit includes a first wiring, a second wiring, a third wiring, a fourth wiring, a first overlap area, a second overlap area, a multi-cut via, the multi-cut via including a first via and a second via formed in the first direction, and a single-cut via formed to connect the third wiring to the fourth wiring in the second overlap area. A width of the second portion of the second wiring corresponding to a first direction is longer than a width of the first portion of the second wiring corresponding to the first direction. A distance between the center of the first via and the center of the second via is longer than the width of the first portion of second wiring.

Abstract: A method for fabricating an integrated circuit structure and the resulting integrated circuit structure are provided. The method includes forming a low-k dielectric layer; form an opening in the low-k dielectric layer; forming a barrier layer covering a bottom and sidewalls of the low-k dielectric layer; performing a treatment to the barrier layer in an environment comprising a treatment gas; and filling the opening with a conductive material, wherein the conductive material is on the barrier layer.

Abstract: Provided are a three-dimensional (3D) interconnection structure and a method of manufacturing the same. The 3D interconnection structure includes a wafer that has one side of an inverted V-shape whose middle portion is convex and a lower surface having a U-shaped groove for mounting a circuit, and a first electrode formed to cover a part of the inverted V-shaped one side of the wafer and a part of the U-shaped groove.

Abstract: The adhesive composition of the invention comprises a radical generator, a thermoplastic resin and a urethane (meth)acrylate having two or more radical-polymerizing groups in the molecule and a weight-average molecular weight of 3000-30,000.

Abstract: Various methods and apparatus for establishing thermal pathways for a semiconductor device are disclosed. In one aspect, a method of manufacturing is provided that includes providing a first semiconductor chip that has a substrate and a first active circuitry portion extending a first distance into the substrate. A barrier is formed in the first semiconductor chip that surrounds but is laterally separated from the first active circuitry portion and extends into the substrate a second distance greater than the first distance.

Abstract: A wiring substrate for a semiconductor chip includes a substrate, first and second wiring layers and a plurality of first and second bonding pads. The substrate has a first surface and a second surface opposite to the first surface, a window extending from the first surface to the second surface to expose chip pads of a semiconductor chip adherable to the first surface. The first and second wiring layers of a multi-layered structure are sequentially formed on the second surface of the substrate with at least one insulation layer interposed between the first and second wiring layers. A plurality of the first and second bonding pads are respectively connected to the first and second wiring layers, the first and second bonding pads having a concavo-convex arrangement on the second surface of the substrate along a side of the window.

Abstract: A semiconductor manufacturing method includes attaching a first die to a substrate panel. The method also includes applying a mold compound after attaching the first die to the substrate panel to the first die and the substrate panel. The method further includes thinning the first die and the mold compound after applying the mold compound. Attaching the die to the substrate panel before thinning eliminates usage of a carrier wafer when processing thin semiconductors.

Abstract: According to one embodiment, a semiconductor module comprises a substrate, a first wiring, an electrode pad, a junction, an oscillator, and a detector. The first wiring is disposed on the substrate, and has a characteristic impedance Z0. The electrode pad is connected to the first wiring. The junction is disposed on the electrode pad, and has an impedance Z1. The oscillator is disposed in contact with the first wiring, and oscillates a pulse wave of a voltage toward the junction via the first wiring. The detector is disposed in contact with the first wiring, and detects an output wave of the pulse wave from the junction. The characteristic impedance Z0 and the impedance Z1 satisfy a following relationship (1), ? Z ? ? 0 - Z ? ? 1 Z ? ? 0 ? ? 0.05 .

Abstract: A semiconductor module comprises components in one wafer level package. The module comprises an integrated circuit (IC) chip embedded within a package molding compound. The package comprises a molding compound package layer coupled to an interface layer for integrating an antenna structure and a bonding interconnect structure to the IC chip. The bonding interconnect structure comprises three dimensional interconnects. The antenna structure and bonding interconnect structure are coupled to the IC chip and integrated within the interface layer in the same wafer fabrication process.

Abstract: A semiconductor device including a first insulating film formed above a semiconductor substrate and having a first relative dielectric constant; a second insulating film formed above the first insulating film and having a second relative dielectric constant greater than the first relative dielectric constant; a plurality of columnar plugs extending longitudinally through the first and the second insulating films having a first sidewall extending through the first insulating film and a second sidewall extending through the second insulating film, wherein the second sidewall is tapered; a third insulating film formed above the second insulating film and having a third relative dielectric constant less than the second relative dielectric constant of the second insulating film; trenches extending through the third insulating film and reaching an upper portion of the plugs; and an interconnect wiring comprising metal formed within the trenches and contacting the upper portion of the plugs.

Abstract: A zipper structure includes a first contiguous full-dense-mesh (FDM) array of a first circuit in top metal and a second contiguous FDM array of a second circuit in top-1 metal, a third contiguous FDM array of the second circuit in top metal and a fourth contiguous FDM array of the first circuit in top-1 metal, and a signal line, such that portions of the first contiguous FDM array and the second contiguous FDM array overlap and portions of the third contiguous FDM array and the fourth contiguous FDM array overlap. The Zipper structure facilitates connecting the first contiguous FDM array to the fourth contiguous FDM array by vias and a first connector lines and the second contiguous FDM array to the third contiguous FDM array by vias and a second connector lines, such that portion of the signal line overlaps with the first connector lines and the second connector lines.

Abstract: CMOS inverters are included in a standard cell. Power supply lines are electrically connected to CMOS inverters, and include lower layer interconnects and upper layer interconnect. Lower layer interconnects extend along a boundary of standard cells adjacent to each other and on the boundary. Upper layer interconnects are positioned more inside in standard cell than lower layer interconnects, as viewed from a plane. CMOS inverters are electrically connected through upper layer interconnects to lower layer interconnects. Thus, a semiconductor device is obtained that can achieve both higher speeds and higher integration.

Abstract: Disclosed are embodiments of a circuit and method for electroplating a feature (e.g., a BEOL anti-fuse device) onto a wafer. The embodiments eliminate the use of a seed layer and, thereby, minimize subsequent processing steps (e.g., etching or chemical mechanical polishing (CMP)). Specifically, the embodiments allow for selective electroplating metal or alloy materials onto an exposed portion of a metal layer in a trench on the front side of a substrate. This is accomplished by providing a unique wafer structure that allows a current path to be established from a power supply through a back side contact and in-substrate electrical connector to the metal layer. During electrodeposition, current flow through the current path can be selectively controlled. Additionally, if the electroplated feature is an anti-fuse device, current flow through this current path can also be selectively controlled in order to program the anti-fuse device.

Abstract: A wiring board includes a core substrate including an insulation base member; linear conductors configured to pierce from a first surface of the insulation base member to a second surface of the insulation base member; a ground wiring group including a first ground wiring formed on the first surface of the core substrate, and a belt-shaped second ground wiring formed on the second surface of the core substrate and electrically connected to the first ground wiring by way of a part of the linear conductors; and an electric power supply wiring group including a first electric power supply wiring formed on the first surface, and a second electric power supply wiring formed on the second surface and electrically connected to the first electric power supply wiring by way of a part of the plural linear conductors.

Abstract: In a semiconductor device package having a stress relief spacer, and a manufacturing method thereof, metal interconnect fingers extend from the body of a chip provide for chip interconnection. The metal fingers are isolated from the body of the chip by a stress-relief spacer. In one example, such isolation takes the form of an air gap. In another example, such isolation takes the form of an elastomer material. In either case, mismatch in coefficient of thermal expansion between the metal interconnect fingers and the body of the chip is avoided, alleviating the problems associated with cracking and delamination, and leading to improved device yield and device reliability.

Abstract: An electronic component includes: a semiconductor substrate having a first surface and a second surface opposing to the first surface; a trans-substrate conductive plug that penetrates the semiconductor substrate from the first surface to the second surface; an electronic element provided in the vicinity of the first surface of the semiconductor; and a sealing member that seals the electronic element between the sealing member and the first surface, wherein the electronic element is electrically connected to the trans-substrate conductive plug.

Abstract: A copper interconnect structure has an intrinsic graphene cap for improving back end of line (BEOL) reliability of the interconnect by reducing time-dependent dielectric breakdown (TDDB) failure and providing resistance to electromigration. Carbon atoms are selectively deposited onto a copper layer of the interconnect structure by a deposition process to form a graphene cap. The graphene cap increases the activation energy of the copper, thus allowing for higher current density and improved resistance to electromigration of the copper. By depositing the graphene cap on the copper, the dielectric regions remain free of conductors and, thus, current leakage within the interlayer dielectric regions is reduced, thereby reducing TDDB failure and increasing the lifespan of the interconnect structure. The reduction of TDDB failure and improved resistance to electromigration improves BEOL reliability of the copper interconnect structure.

Abstract: An integrated circuit structure includes a semiconductor chip, a metal pad at a major surface of the semiconductor chip, and an under-bump metallurgy (UBM) over and contacting the metal pad. A metal bump is formed over and electrically connected to the UBM. A dummy pattern is formed at a same level, and formed of a same metallic material, as the metal pad.

Abstract: In a layout structure capable of independent supply of a substrate or well potential from a power supply potential, further reduction in layout area is achieved. A reinforcing power supply cell is inserted in a cell line in which a plurality of cells are arranged in series. Each of the cells includes an impurity doped region for supplying a substrate or well potential NWVDD which is different from a positive power supply potential VDD to a p-type transistor arranging region. The reinforcing power supply cell includes a power supply impurity doped region to which an impurity doped region of an adjacent cell is electrically connected and a power supply wire provided in a wiring layer formed above the power supply impurity doped region and electrically connected to the power supply impurity doped region.

Abstract: A method for manufacturing an interconnection wiring structure of a semiconductor device includes forming an isolation region, which arranges active regions in a diagonal direction, in a semiconductor substrate; forming first damascene trenches, which open upper portions of a bit line contacts, by selectively etching a second interlayer insulation layer; forming bit lines which fill the first damascene trenches; forming second damascene trenches, which expose portions of the active region, by selectively etching the portion of a second interlayer insulation layer between the bit lines and the portion of the first interlayer insulation layer thereunder; attaching trench spacer on side walls of the second damascene trench; forming storage node contact lines which fill the second damascene trenches.

Abstract: Embodiments of the current invention describe a method of plating platinum selectively on a copper film using a self-initiated electroless process. In particular, platinum films are plated onto very thin copper films having a thickness of less than 300 angstroms. The electroless plating solution and the resulting structure are also described. This process has applications in the semiconductor processing of logic devices, memory devices, and photovoltaic devices.

Abstract: A semiconductor device of the invention include a rectangular semiconductor element mounted on a substrate formed with an external input terminal, an external output terminal, and a plurality of wiring patterns connected to each of the external input terminal and the external output terminal. The semiconductor element comprises, a plurality of first electrodes formed along a first edge of a surface thereof, a plurality of second electrodes formed along an edge opposite to the first edge of the surface, a plurality of third electrodes formed in the neighborhood of a functional block, and an internal wiring for connecting the first electrodes and the third electrodes. The substrate comprises, a first wiring pattern for connecting the external input terminal and the first electrodes, a second wiring pattern for connecting the external output terminal and the second electrodes, and a third wiring pattern for connecting the first electrodes and the third electrodes.

Abstract: An integrated circuit may include one or more cells, with each cell comprising a first and a second input terminal, a first and a second output terminal, and a number of connection stages configured to couple each input terminal to a corresponding respective output terminal. The stages may include one stage per metal layer of the integrated circuit and one stage per VIA layer of the integrated circuit. Each stage may be configured with a pair of input ports and a pair of output ports. Each output port of a stage may serially connect to a corresponding respective input port of a first adjacent stage, and each input port of the stage may also serially connect to a corresponding respective output port of a second adjacent stage. The pair of input ports may also be configured to programmably connect to the pair of output ports within the same stage, according to one of two different connection patterns, to establish a respective connection within the stage.

Abstract: In a semiconductor device package having a stress relief spacer, and a manufacturing method thereof, metal interconnect fingers extend from the body of a chip provide for chip interconnection. The metal fingers are isolated from the body of the chip by a stress-relief spacer. In one example, such isolation takes the form of an air gap. In another example, such isolation takes the form of an elastomer material. In either case, mismatch in coefficient of thermal expansion between the metal interconnect fingers and the body of the chip is avoided, alleviating the problems associated with cracking and delamination, and leading to improved device yield and device reliability.

Abstract: An integrated circuit chip includes a semiconductor substrate having thereon a plurality of IMD layers and first conductive layers embedded in the IMD layers; a first insulating layer overlying the IMD layers and the first conductive layers; a plurality of first power/ground mesh wiring lines, in a second conductive layer overlying the first Insulating layer, for distributing power signal or ground signal; and a second insulating layer covering the second conductive layer and the first insulating layer.

Abstract: A method of fabricating an interconnect structure is provided. The method includes forming a hybrid photo-patternable dielectric material atop a substrate. The hybrid photo-patternable dielectric material has dual-tone properties with a parabola like dissolution response to radiation. The hybrid photo-patternable dielectric material is then image-wise exposed to radiation such that a self-aligned pitch split pattern forms. A portion of the self-aligned split pattern is removed to provide a patterned hybrid photo-patternable dielectric material having at least one opening therein. The patterned hybrid photo-patternable dielectric material is then converted into a cured and patterned dielectric material having the at least one opening therein. The at least one opening within the cured and patterned dielectric material is then filed with at least an electrically conductive material. Also provided are a hybrid photo-patternable dielectric composition and an interconnect structure.

Abstract: A higher aspect ratio for upper level metal interconnects is described for use in higher frequency circuits. Because the skin effect reduces the effective cross-sectional area of conductors at higher frequencies, various approaches are described to reduce the effective RC delay in interconnects.

Abstract: A flexible semiconductor package apparatus having a responsive bendable conductive wire member is presented. The apparatus includes a flexible substrate, semiconductor chips, and conductive wires. The semiconductor chips are disposed on the flexible substrate and spaced apart from each other on the flexible substrate. Each semiconductor chip has bonding pads. The conductive wires are electrically connected to the bonding pads of the semiconductor chip. Each conductive wire has at least one elastic portion. One preferred configuration is that part of the conductive wire is wound to form a coil spring shape so that the coil spring shape of the conductive wire aid in preventing the conductive wire from being separated from the corresponding bonding pad of the semiconductor chip when the flexible substrate on which the semiconductor chips are mounted are bent, expanded or twisted.

Abstract: A metal wiring of a semiconductor device includes a semiconductor substrate; an insulating layer provided with a damascene pattern formed over the semiconductor substrate; a diffusion barrier layer which contains a RuO2 layer formed on a surface of the damascene pattern and an Al deposit-inhibiting layer formed on a portion of the RuO2 layer in both-side upper portion of the damascene pattern; and a wiring metal layer including Al formed on the diffusion barrier layer by MOCVD method in order to fill the damascene pattern.

Abstract: In a multi-chip semiconductor device, a second semiconductor chip is stacked on a first semiconductor chip with an adhesive layer being interposed therebetween, and the first and second semiconductor chips are sealed by resin containing a mixture of, e.g., a filler. The first semiconductor chip includes a first region on a surface of which the second semiconductor chip is stacked, and a second region on a surface of which the second semiconductor chip does not stacked. In one of interconnect layers including an uppermost layer, a wiring pattern is not provided, which extends across a border between the first and second regions.

Abstract: Example embodiments of the present invention relate to an interposer of a semiconductor device having an air gap structure, a semiconductor device using the interposer, a multi-chip package using the interposer and methods of forming the interposer. The interposer includes a semiconductor substrate including a void, a metal interconnect, provided within the void, thereby forming an air gap insulating the metal interconnect. The metal interconnect may be connected to a contact element, and may be maintained within the air gap using the contact element.

Abstract: Embodiments of the invention relates to a metal thin film connection structure, comprising a first metal layer pattern; a second metal layer pattern which is separately disposed with the first metal layer pattern; a first insulating layer formed on the first metal layer pattern and the second metal layer pattern; a plurality of first via holes formed over the first metal layer pattern; a plurality of second via holes formed over the second metal layer pattern; and a plurality of third metal layer patterns formed on the first insulating layer, the third metal layer patterns being filled in the first via holes and the second via holes and electrically connect the first metal layer pattern and the second metal layer pattern through the first and second via holes. The embodiments of the invention also provide an array substrate comprising the metal thin film connection structure and a manufacturing method for the metal thin film connection structure.

Abstract: A semiconductor apparatus has a configuration in which multiple copper wiring layers and multiple insulating layers are alternately layered. A low-impedance wiring is formed occupying a predetermined region. A first wiring pattern includes multiple copper wiring members arranged in parallel with predetermined intervals in a first copper wiring layer, each of which has a rectangular shape extending in a first direction. A second wiring pattern includes multiple copper wiring members arranged in parallel with predetermined intervals in a second copper wiring layer adjacent to the first copper wiring layer, each of which has a rectangular shape extending in a second direction orthogonal to the first direction. The region occupied by the first wiring pattern and that occupied by the second wiring pattern are arranged such that they at least overlap. The first wiring pattern and the second wiring pattern are electrically connected so as to have the same electric potential.

Abstract: The present invention discloses a MEMS (Micro-Electro-Mechanical System) integrated chip with cross-area interconnection, comprising: a substrate; a MEMS device area on the substrate; a microelectronic device area on the substrate; a guard ring separating the MEMS device area and the microelectronic device area; and a conductive layer on the surface of the substrate below the guard ring, or a well in the substrate below the guard ring, as a cross-area interconnection electrically connecting the MEMS device area and the microelectronic device area.

Abstract: A semiconductor process includes the following steps. Firstly, a conductive substrate is provided. Then, at least one insulating pattern is formed on the conductive substrate. Thereafter at least one metal pattern is formed on the insulating pattern. After that, a passivation layer is formed on the conductive substrate to cover the metal pattern by an electroplating process.

Abstract: An improved metal interconnect is formed with reduced metal voids and dendrites. An embodiment includes forming a mask layer on a dielectric layer, forming openings in the mask and dielectric layers, depositing a planarization layer over the mask layer and filling the openings, planarizing to remove the mask layer, removing the planarization layer from the openings, and filling the openings with metal. The planarization step prior to depositing the metal removes the etch undercut that occurs during formation of the openings and reduces the aspect ratio in the openings, thereby improving metal fill uniformity.

Abstract: A semiconductor device having a via chain circuit including a plurality of fine interconnections and an extension interconnection wider than the fine interconnections, having a first end connected to one or more of the fine interconnections and a second end located in an area of the semiconductor device external to the via chain circuit. One or more of the fine interconnections becomes wider gradually towards the connection to the extension interconnection. The extension interconnection is formed in a same layer as the one or more of the fine interconnections connected to the extension interconnection. The one or more of the fine interconnections connected to the extension interconnection is connected to the extension interconnections at a position where the fine interconnections become wider.

Abstract: There is disclosed a semiconductor device comprising a first metal wiring buried in a first wiring groove formed, via a first barrier metal, in a first insulating layer formed on a semiconductor substrate, a second insulating layer formed on the first metal wiring, a via plug formed of a metal buried, via a second barrier metal, in a via hole formed in the second insulating layer, a third insulating layer formed on the second insulating layer in which the via plug is buried, and a second metal wiring buried in a second wiring groove formed in the third insulating layer via a third barrier metal having a layer thickness of layer quality different from that of the second barrier metal.