Abstract: A method for enhancing internal layer-layer thermal interface performance and a chip stack of semiconductor chips using the method. The method includes adding a thermosetting polymer to the thermal interface material, dispersing a plurality of nanofibers into the thermal interface material, and un-crosslinking the thermosetting polymer in the thermal interface material. The method further includes extruding the thermal interface material through a die to orient the conductive axis of the nanofibers and polymer chains in the desired direction, and re-crosslinking the thermosetting polymer in the thermal interface material. The chip stack includes a first chip with circuitry on a first side, a second chip coupled to the first chip by a grid of connectors, and a thermal interface material pad between the chips. The thermal interface includes nanofibers and a polymer that allows for optimal alignment of the nanofibers and polymer chains.

Abstract: A structure includes a thermal interface material, and a Perforated Foil Sheet (PFS) including through-openings therein, with a first portion of the PFS embedded in the thermal interface material. An upper layer of the thermal interface material is overlying the PFS, and a lower layer of thermal interface material is underlying the PFS. The thermal interface material fills through-openings in the PFS.

Abstract: A semiconductor package and a method of manufacturing the same are disclosed, wherein the semiconductor package includes a circuit board, a semiconductor chip mounted on the circuit board, an encapsulant positioned on the circuit board and encapsulating the semiconductor chip to the circuit board, and a thermal dissipating member positioned on the encapsulant and having a heat spreader that dissipates a driving heat from the semiconductor chip and a heat capacitor that absorbs excess driving heat that exceeds a heat transfer capability of the heat spreader, such that when a high power is applied to the package, the excess heat is absorbed into the heat capacitor as a latent heat and thus the semiconductor chip is protected from an excessive temperature increase caused by the excess heat, thereby increasing a critical time and performance duration time of the semiconductor package.

Abstract: A device includes a semiconductor chip including a first main face and a second main face, the second main face being the backside of the semiconductor chip. The second main face includes a first region and a second region, the second region being a peripheral region of the second main face. The device further includes a dielectric material arranged over the second region and an electrically conductive material arranged over the first region.

Abstract: A semiconductor package process includes the following steps, providing a first substrate having a first metal bump, the first metal bump comprises a joint portion having a first softening point; providing a second substrate having a second metal bump having a top surface, a lateral surface and a second softening point, wherein the first softening point is smaller than the second softening point; performing a heating procedure to make the joint portion of the first metal bump become a softened state; and laminating the first substrate on the second substrate to make the second metal bump embedded into the joint portion in the softened state to make the top surface and the lateral surface of the at least one second metal bump being clad extendedly by compressing the joint portion in the softened state.

Abstract: Electronic assemblies and methods including the formation of interconnect structures are described. In one embodiment an apparatus includes semiconductor die and a first metal bump on the die, the first metal bump including a surface having a first part and a second part. The apparatus also includes a solder resistant coating covering the first part of the surface and leaving the second part of the surface uncovered. Other embodiments are described and claimed.

Abstract: A semiconductor device includes a bonding pad on a semiconductor substrate, a bump on the bonding pad, a solder on the bump, and an anti-wetting layer between the bump and the solder extending along a sidewall of the bump, the anti-wetting layer having a first thickness T1 along the sidewall of the bump closer to the solder and a second thickness T2 along the sidewall of the bump closer to the bonding pad, wherein T2<T1.

Abstract: An electronic component includes a plurality of electrodes provided in a rectangular or substantially rectangular box-shaped area on an upper surface of a substrate, an electronic component element mounted on the substrate by flip-chip bonding, and an identification mark. The identification mark is provided between a first electrode, which is arranged along one side of the rectangular or substantially rectangular box-shaped area, and a second electrode, which is adjacent to the first electrode along the one side, of the plurality of electrodes provided on the upper surface of the substrate, and is located on or outside a line connecting the outer side edges of the first and second electrodes.

Abstract: This invention provides a multi-pin semiconductor device as a low-cost flip-chip BGA. In the flip-chip BGA, a plurality of signal bonding electrodes in a peripheral area of the upper surface of a multilayer wiring substrate are separated into inner and outer ones and a plurality of signal through holes coupled to a plurality of signal wirings drawn inside are located between a plurality of rows of signal bonding electrodes and a central region where a plurality of bonding electrodes for core power supply are located so that the chip pad pitch can be decreased and the cost of the BGA can be reduced without an increase in the number of layers in the multilayer wiring substrate.

Abstract: A semiconductor device includes a semiconductor chip, wiring that is included in the semiconductor chip and has a coupling part between parts with different widths, a pad being formed above the wiring and in a position overlapping the coupling part, a bump being formed on the pad, a buffer layer being formed in a position between the coupling part and the pad so as to cover the entire coupling part, and inorganic insulating layers being formed between the wiring and the buffer layer and between the buffer layer and the pad, respectively.

Abstract: A microelectronic assembly includes a first component with first conductive elements; a second component with second conductive elements; a bond metal; and an underfill layer. The posts have a height above the respective surface from which the posts project. A bond metal can be disposed between respective pairs of conductive elements, each pair including at least one of the posts and at least one of the first or second conductive elements confronting the at least one post. The bond metal can contact edges of the posts along at least one half the height of the posts. An underfill layer contacts and bonds the first and second surfaces of the first and second components. A residue of the underfill layer may be present at at least one interfacial surfaces between at least some of the posts and the bond metal or may be present within the bond metal.

Abstract: 3D integrated circuit packages with through-mold first level interconnects and methods to form such packages are described. For example, a semiconductor package includes a substrate. A bottom semiconductor die has an active side with a surface area. The bottom semiconductor die is coupled to the substrate with the active side distal from the substrate. A top semiconductor die has an active side with a surface area larger than the surface area of the bottom semiconductor die. The top semiconductor die is coupled to the substrate with the active side proximate to the substrate. The active side of the bottom semiconductor die is facing and conductively coupled to the active side of the top semiconductor die. The top semiconductor die is conductively coupled to the substrate by first level interconnects that bypass the bottom semiconductor die.

Abstract: A package-on-package device includes memory chips side-by-side on a package substrate. Accordingly, it is possible to reduce a thickness of a semiconductor package. Further, data and command pads of a logic chip may be located to be adjacent to data and command pads of the memory chips. Accordingly, a routing distance between pads can be contracted and thus signal delivery speed can be improved. This makes it possible to improve an operation speed of the device.

Abstract: A wafer-leveled chip packaging method, comprising the steps of: providing a wafer; attaching at least one first chip to the wafer; forming a first insulating layer on the wafer; forming a plurality of first conductive vias penetrating the first insulating layer, wherein parts of the first conductive vias are electrically connected with the first chip; forming a conductive pattern layer on the surface of the first insulating layer wherein the conductive pattern layer is electrically connected with the first conductive vias; forming a plurality of through holes penetrating the wafer; filling a second insulating layer in the through holes; and forming a plurality of second conductive vias in the second insulating layer, wherein the second conductive vias are electrically connected with the first conductive vias.

Abstract: One illustrative method disclosed herein includes forming a trench/via in a layer of insulating material, forming a barrier layer in the trench/via, forming a copper-based seed layer on the barrier layer, converting at least a portion of the copper-based seed layer into a copper-based nitride layer, depositing a bulk copper-based material on the copper-based nitride layer so as to overfill the trench/via and performing at least one chemical mechanical polishing process to remove excess materials positioned outside of the trench/via to thereby define a copper-based conductive structure. A device disclosed herein includes a layer of insulating material, a copper-based conductive structure positioned in a trench/via within the layer of insulating material and a copper-based silicon or germanium nitride layer positioned between the copper-based conductive structure and the layer of insulating material.

Abstract: Among other things, one or more support structures and techniques for forming such support structures within semiconductor devices are provided. The support structure comprises an oxide infused silicon layer that is formed within a trench of a dielectric layer on a substrate of a semiconductor device. The oxide infused silicon layer results from a silicon layer that is exposed to oxide during an ultraviolet (UV) curing process. The oxide infused silicon layer is configured to support a barrier layer against a conductive structure formed on the barrier layer within the trench. In this way, the support structure provides pressure against the barrier layer so that the barrier layer substantially maintains contact with the conductive structure, to promote improved performance and reliability of the conductive structure.

Abstract: To achieve the foregoing and in accordance with the purpose of the present invention, a method for filling through silicon vias is provided. A dielectric layer is formed over the through silicon vias. A barrier layer, comprising tungsten, is deposited by CVD or ALD over the dielectric layer. The through silicon vias are filled with a conductive material.

Abstract: A semiconductor device includes a dielectric layer positioned above a substrate of the semiconductor device and a recess defined in the dielectric layer. An adhesion barrier layer is positioned on and in direct contact with at least the sidewalls of the recess, a barrier layer interface being defined where the adhesion barrier layer directly contacts the dielectric layer. A stress-reducing barrier layer is positioned adjacent to the adhesion barrier layer, wherein the stress-reducing barrier layer is adapted to reduce a stress level across the barrier layer interface from a first stress level to a second stress level that is less than the first stress level. At least one layer of a conductive fill material is positioned over the stress-reducing barrier layer, the at least one layer of the conductive fill material substantially filling the recess.

Abstract: An interconnect structure and method of fabricating the same is provided. More specifically, the interconnect structure is a defect free capped interconnect structure. The structure includes a conductive material formed in a trench of a planarized dielectric layer which is devoid of cap material. The structure further includes the cap material formed on the conductive material to prevent migration. The method of forming a structure includes selectively depositing a sacrificial material over a dielectric material and providing a metal capping layer over a conductive layer within a trench of the dielectric material. The method further includes removing the sacrificial material with any unwanted deposited or nucleated metal capping layer thereon.

Abstract: An electrical connecting element for connecting a first substrate and a second substrate and a method for manufacturing the same are disclosed. The method of the present invention comprises: (A) providing a first substrate and a second substrate, wherein a first copper film is formed on the first substrate, a first metal film is formed on the second substrate, a first connecting surface of the first copper film has a (111)-containing surface, and the first metal film has a second connecting surface; and (B) connecting the first copper film and the first metal film to form an interconnect, wherein the first connecting surface of the first copper film is faced to the second connecting surface of the first metal film.

Abstract: Provided is a semiconductor device configured to prevent a penetration of moisture into an internal circuit. The moisture from a bonding pad to the internal circuit is blocked by providing an underlying polysilicon film (10) formed as a lower layer of a bonding pad, a bonding pad (1) formed above the underlying polysilicon film (10) through intermediation of an inter-layer insulation film (21), and an outer circumferential interconnecting line (3) formed so as to surround an outer side of the bonding pad 1, and by connecting the outer circumferential interconnecting line (3) and the underlying polysilicon film (10) with a continuous outer circumferential contact.

Abstract: In a provided mounting structure, an electronic component such as a semiconductor chip having a fragile film is mounted on a substrate such as a circuit board with higher connection reliability. A junction that connects an electrode terminal (4) of an electronic component (1) and an electrode terminal (5) of a substrate (2) contains an alloy (8) and a metal (9) having a lower modulus of elasticity than the alloy (8). The junction has a cross section structure in which the alloy (8) is surrounded by the metal (9) having the lower modulus of elasticity.

Abstract: Various embodiments provide a power transistor arrangement. The power transistor arrangement may include a carrier; a first power transistor having a control electrode and a first power electrode and a second power electrode; and a second power transistor having a control electrode and a first power electrode and a second power electrode. The first power transistor and the second power transistor may be arranged next to each other on the carrier such that the control electrode of the first power transistor and the control electrode of the second power transistor are facing the carrier.

Abstract: A semiconductor device includes a semiconductor die. An encapsulant is disposed around the semiconductor die to form a peripheral area. An interconnect structure is formed over a first surface of the semiconductor die and encapsulant. A plurality of vias is formed partially through the peripheral area of the encapsulant and offset from the semiconductor die. A portion of the encapsulant is disposed over a second surface of the semiconductor die opposite the first surface. The plurality of vias comprises a depth greater than a thickness of the portion of the encapsulant. A first portion of the plurality of vias is formed in a row offset from a side of the semiconductor die. A second portion of the plurality of vias is formed as an array of vias offset from a corner of the semiconductor die. A repair material disposed within the plurality of vias.

Abstract: According to one embodiment, a semiconductor memory device includes a plurality of interconnects of an nth layer, a plurality of interconnects of a (n+1)th layer, a plurality of stacked films of the nth layer, each of the plurality of stacked films of the nth layer including a memory element, an inter-layer insulating film of the nth layer, a plurality of interconnects of a (n+2)th layer, a plurality of stacked films of the (n+1)th layer, each of the plurality of stacked films of the (n+1)th layer including a memory element, and an inter-layer insulating film of the (n+1)th layer. The inter-layer insulating film of the (n+1)th layer is provided also at a side surface of an end portion in the first direction of the interconnects of the nth layer.

Abstract: An apparatus including a die including a first side and an opposite second side including a device side with contact points and lateral sidewalls defining a thickness of the die; a primary core adjacent at least a pair of the lateral sidewalls of the die; and a build-up carrier coupled to the second side of the die, the build-up carrier including a plurality of alternating layers of conductive material and insulating material, wherein at least one of the layers of conductive material is coupled to one of the contact points of the die. A method of forming a package and an apparatus including a computing device including a package are also disclosed.

Abstract: The present invention includes a plate electrode to be a plate-shaped electrode member, an epoxy sheet serving as an integrated insulating sheet and provided on the plate electrode, a double printed board serving as a control board and provided on the epoxy sheet, and a board integrated electrode in which the plate electrode and the double printed board are formed integrally by the epoxy sheet.

Abstract: The present invention provides a semiconductor device. The semiconductor device comprises: a metal pad and a first specific metal layer routing. The metal pad is positioned on a first metal layer of the semiconductor device. The first specific metal layer routing is formed on a second metal layer of the semiconductor device, and directly under the metal pad.

Abstract: Provided is a semiconductor package with improved mounting property. A concave portion is provided in an insulating resin between an island for mounting a semiconductor chip thereon and an opposing lead, to thereby prevent contact between solder printed on a circuit board and the insulating resin. Self-alignment property in melting solder is improved to increase an effective bonding area.

Abstract: A semiconductor device includes a via structure and a conductive structure. The via structure has a surface with a planar portion and a protrusion portion. The conductive structure is formed over at least part of the planar portion and not over at least part of the protrusion portion of the via structure. For example, the conductive structure is formed only onto the planar portion and not onto any of the protrusion portion for forming high quality connection between the conductive structure and the via structure.

Abstract: A semiconductor device includes a first die having a first active surface and a first backside surface opposite the first active surface, a second die having a second active surface and a second backside surface opposite the second active surface, and an interposer, the first active surface of the first die being electrically coupled to a first side of the interposer, the second active surface of the second die being electrically coupled to a second side of the interposer. The semiconductor device also includes a first connector over the interposer, a first encapsulating material surrounding the second die, the first encapsulating material having a first surface over the interposer, and a via electrically coupling the first connector and the interposer. A first end of the via is substantially coplanar with the first surface of the first encapsulating material.

Abstract: An interconnection structure for a package is disclosed. The interconnection structure includes a substrate body having a conductive portion formed on a surface thereof; a first photosensitive dielectric layer formed on the surface of the substrate body and having a via for exposing the conductive potion; a conductive via formed in the via; a second photosensitive dielectric layer formed on the first photosensitive dielectric layer and having a opening for exposing the conductive via and a portion of the first photosensitive dielectric layer; and a conductive trace layer formed in the opening of the second photosensitive dielectric layer so as to be electrically connected to the conductive portion through the conductive via, thereby simplifying the fabrication process and reducing the fabrication cost and time.

Abstract: A three-dimensional monolithic electronic-photonic integrated circuit and a method of manufacturing the same. The electronic-photonic integrated circuit may include a photonic element formed in a sealed space of a substrate and an electronic element formed on the substrate. The substrate may include a first substrate and a second substrate that are bonded to each other. The first substrate having a first trench corresponding to the sealed space formed therein, a first surface of the second substrate having the photonic element formed thereon, and the sealed space defined by a space formed inside the first trench that is sealed by the first surface of the second substrate.

Abstract: A component can include a substrate and a conductive via extending within an opening in the substrate. The substrate can have first and second opposing surfaces. The opening can extend from the first surface towards the second surface and can have an inner wall extending away from the first surface. A dielectric material can be exposed at the inner wall. The conductive via can define a relief channel within the opening adjacent the first surface. The relief channel can have an edge within a first distance from the inner wall in a direction of a plane parallel to and within five microns below the first surface, the first distance being the lesser of one micron and five percent of a maximum width of the opening in the plane. The edge can extend along the inner wall to span at least five percent of a circumference of the inner wall.

Abstract: An improvement in the manufacturing efficiency of a circuit substrate and a semiconductor module where a semiconductor device including electrodes on a front and a back surface is mounted. [Solution] A semiconductor module includes a wiring substrate where a via and a interconnecting pattern are formed, a semiconductor device disposed on a first surface side of the wiring substrate, and a bonding portion including a first bonding layer disposed on the wiring substrate side and a second bonding layer disposed on the semiconductor device side.

Abstract: A semiconductor wafer has a plurality of semiconductor die separated by a peripheral region. A trench is formed in the peripheral region of the wafer. A via is formed on the die. The trench extends to and is continuous with the via. A first conductive layer is deposited in the trench and via to form conductive TSV. The first conductive layer is conformally applied or completely fills the trench and via. The trench has a larger area than the vias which accelerates formation of the first conductive layer. A second conductive layer is deposited over a front surface of the die. The second conductive layer is electrically connected to the first conductive layer. The first and second conductive layers can be formed simultaneously. A portion of a back surface of the wafer is removed to expose the first conductive layer. The die can be electrically interconnected through the TSVs.

Abstract: Disclosed herein is a method of forming a device, comprising mounting a plurality of first interconnects on one or more first integrated circuit dies. One or more second integrated circuit dies are mounted on a first side of an interposer. The interposer is mounted to at a second side to the first integrated circuit dies, the plurality of first interconnects disposed outside of the interposer. The interposer is mounted to a first side of a substrate by attaching the first interconnects to the substrate, the substrate in signal communication with one or more of the first integrated circuit dies through the first interconnects.

Abstract: A stacked multilayer structure according to an embodiment of the present invention comprises: a stacked layer part including a plurality of conducting layers and a plurality of insulating layers, said plurality of insulating layers being stacked alternately with each layer of said plurality of conducting layers, one of said plurality of insulating layers being a topmost layer among said plurality of conducting layers and said plurality of insulating layers; and a plurality of contacts, each contact of said plurality of contacts being formed from said topmost layer and each contact of said plurality of contacts being in contact with a respective conducting layer of said plurality of conducting layers, a side surface of each of said plurality of contacts being insulated from said plurality of conducting layers via an insulating film.

Abstract: An electronic fuse structure including an Mx level comprising an Mx metal, and an Mx+1 level above the Mx level, the Mx+1 level including an Mx+1 metal and a via electrically connecting the Mx metal to the Mx+1 metal in a vertical orientation, where the Mx+1 metal comprises a thick portion and a thin portion, and where the Mx metal, the Mx+1 metal, and the via are substantially filled with a conductive material.

Abstract: An integrated device includes a die attach pad, a main die, a stacked die, and a mold compound. The main die has a first (e.g., bottom) surface attached to the die attach pad and has a second (e.g., top) surface. The stacked die is attached to the second surface of the main die using, for example, an adhesive film. The main die and the stacked die include silicon crystal. The mold compound encapsulates the die attach pad, the main die, and the stacked die.

Abstract: An integrated circuit film and a method of manufacturing the same are disclosed. The integrated circuit film includes a circuit board containing a circuit route; a first set of pads located on a first surface of the circuit board and configured to be applicable to ISO 7816 standard; and a semiconductor device mounted on the circuit board for communicating with at least one of the first set of pads. The first set of pads are arranged in two rows and the semiconductor device is mounted on the circuit board in a space between the two rows of pads.

Abstract: A method of making a system-in-package device, and a system-in-package device is disclosed. In the method, at least one first species die with predetermined dimensions, at least one second species die with predetermined dimensions, and at least one further component of the system-in-device is included in the system-in package device. At least one of the first and second species dies is selected for redimensioning, and material is added to at least one side of the selected die such that the added material and the selected die form a redimensioned die structure. A connecting layer is formed on the redimensioned die structure. The redimensioned die structure is dimensioned to allow mounting of the non-selected die and the at least one further component into contact with the redimensioned die structure via the connecting layer.

Abstract: A stack package includes a first semiconductor chip having a plurality of first pads, and a second semiconductor chip stacked on the first semiconductor chip and having a plurality of second pads corresponding to the first pads respectively, the second pads connected to the corresponding first pads. The first and second pads are arranged such that the first and second pads overlap with each other even after the first and second semiconductor chips are rotated relative to each other by a predetermined angle.

Abstract: A microelectronic package can include a substrate having first and second opposed surfaces extending in first and second transverse directions and an opening extending between the first and second surfaces and defining first and second distinct parts each elongated along a common axis extending in the first direction, first and second microelectronic elements each having a front surface facing the first surface of the substrate and a column of contacts at the respective front surface, a plurality of terminals exposed at the second surface, and first and second electrical connections aligned with the respective first and second parts of the opening and extending from at least some of the contacts of the respective first and second microelectronic elements to at least some of the terminals. The column of contacts of the first and second microelectronic elements can be aligned with the respective first and second parts of the opening.

Abstract: A method of making an electronic device includes forming an electrically conductive pattern on a substrate, forming a coverlay layer on the substrate and the electrically conductive pattern, forming a partially cured, tacky adhesive layer on the coverlay layer, and forming openings in the coverlay layer and the partially cured, tacky adhesive layer aligned with the electrically conductive pattern. The method includes positioning an IC on the partially cured, tacky adhesive layer and thereafter curing the partially cured tacky adhesive layer to thereby simultaneously mechanically secure and electrically interconnect the IC to the substrate, the IC having bond pads on a surface thereof.

Abstract: Microelectronic components and methods forming such microelectronic components are disclosed herein. The microelectronic components may include a plurality of electrically conductive vias in the form of wire bonds extending from a bonding surface of a substrate, such as surfaces of electrically conductive elements at a surface of the substrate.

Abstract: An electronic device includes: a substrate having first and second surfaces, wherein the first surface is opposite to the second surface; a first electronic element mounted on the first surface of the substrate; a second electronic element mounted on the second surface of the substrate; and a resin mold sealing the first electronic element and the first surface of the substrate. The resin mold further seals the second electronic element on the second surface of the substrate. The second surface of the substrate has a portion, which is exposed from the resin mold. The second electronic element is not disposed on the portion of the second surface.

Abstract: The present application relates to an encapsulating film, an electronic device and a method of manufacturing the same. In the present application, an encapsulating film having excellent moisture blocking property, handleability, workability and durability and a structure including a diode encapsulated with the encapsulating film may be provided.

Abstract: A semiconductor package resin composition of the present invention includes an epoxy resin, a curing agent, inorganic particles, nano-particles surface treated with a silane that contains a photopolymerizable functional group, and a photopolymerization initiator.

Abstract: A scent-releasing mechanism that is usable with an existing air moving device. The scent-releasing mechanism includes a chamber configured to enclose a scent source such as a scent cartridge, scent pad or the like, an air inlet, and an air outlet to release scent into a stream of air moved by the air moving device, so that the scent is dispersed throughout the room. At least one of the air inlet or air outlet is an adjustable port. The adjustable port may be adjusted to control the amount of scent released through the air outlet.