Abstract: A multi-package unit having stacked packages is provided. A multi-package unit may include a first package and a second package mounted on the first package. The first package may be a leadframe package that includes metal leads extending beyond the perimeter of the first package. The first package may include a first integrated circuit die assembled within the first package using the wirebond configuration or the flip-chip configuration. The second package may be a leadframe package or a leadless package that includes a second integrated circuit die. The second package may be smaller than the first package. The first and second integrated circuit dies may be formed using different integrated circuit fabrication technologies.

Abstract: A semiconductor device includes a stack structure of a conductive line and an insulating capping line extending in a first direction on a substrate, a plurality of contact plugs arranged in a row along the first direction and having sidewall surfaces facing the conductive line with air spaces between the sidewall surfaces and the conductive line, and a support interposed between the insulating capping line and the contact plugs to limit the height of the air spaces. The width of the support varies or the support is present only intermittently in the first direction. In a method of manufacturing the semiconductor devices, a sacrificial spacer is formed on the side of the stack structure, the spacer is recessed, a support layer is formed in the recess, the support layer is etched to form the support, and then the remainder of the spacer is removed to provide the air spaces.

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: A printed wiring board includes a first interlayer, a first conductive layer on first-surface side of the first interlayer, a second conductive layer on second-surface side of the first interlayer, a first buildup layer including interlayers and conductive layers and formed on first surface of the first interlayer, and a second buildup layer including interlayers and conductive layers and formed on second surface of the first interlayer. The first conductive layer is formed such that the first conductive layer is embedded in the first interlayer and exposing surface on the first surface of the first interlayer, the second conductive layer is formed on the second surface of the first interlayer, and the interlayers in the first buildup layer include a second interlayer positioned adjacent to the first conductive layer and having the greatest thickness among the first interlayer and interlayers in the first and second buildup layers.

Abstract: A laminate includes a buildup layer having a top and a bottom and a solder mask contacting the top. The laminate also includes a circuit element disposed on the top of the buildup layer and at least partially covered by the solder mask, the circuit element including a first via formed therein that allows for a power signal provided to an underside of the circuit element to be provided to a first connection on a top of the circuit element.

Abstract: A method of forming and testing an interposer includes forming vias in a semiconductor material of a wafer having a front side and a back side. The method further includes disposing an electrically conductive layer on the front side of the wafer such that the layer is electrically connected to the vias. The method also includes forming electrically conductive pads on the front side of the wafer, wherein each electrically conductive pad is electrically connected to the electrically conductive layer. The method further includes forming electrically conductive bumps on the back side of the wafer, wherein each electrically conductive bump is electrically connected to at least one via. The method also includes testing electrical connectivity from a first bump to a second bump of the electrically conductive bumps.

Abstract: The invention provides a circuit substrate and a semiconductor package structure. The circuit substrate includes a core substrate having a chip-side surface and a bump-side surface opposite to the chip-side surface. A first through via plug passes through the core substrate. A first conductive line pattern and a second conductive line pattern adjacent to the first conductive line are disposed on the chip-side surface. A pad is disposed on the bump-side surface. The first through via plug is in direct contact with and partially overlapping the first conductive line pattern and the pad. The first conductive line pattern, the second conductive line pattern and the first through via plug are configured to transmit voltage supplies of the same type.

Abstract: Methods of forming an interconnect structure include depositing a first conductive material on a substrate. Aspects include subtractively etching the conductive material to form a patterned first conductive layer, and depositing a dielectric layer on interconnect structure. Aspects also include depositing a second conductive material on the dielectric layer and removing the second conductive material through the top of the second metal liner.

Abstract: A semiconductor device (1) includes a first metal wiring layer (11) formed on a substrate (10), an interlayer insulating film (12) formed on the first metal wiring layer (11), a second metal wiring layer (23) formed on the interlayer insulating film (12), a first resistor including a first resistance metal film (14a) formed between the first metal wiring layer (11) and the second metal wiring layer (23), a first insulating film (15a) formed on the first resistance metal film (14a), and a second resistance metal film (16a) formed on the first insulating film (15a), and a second resistor including a first resistance metal film (14b) formed between the first metal wiring layer (11) and the second metal wiring layer (23), a first insulating film (15b) formed on the first resistance metal film (14b), and a second resistance metal film (16b) formed on the first insulating film (15b).

Abstract: Semiconductor fuses with nanowire fuse links and fabrication methods thereof are presented. The methods include, for instance: fabricating a semiconductor fuse, the semiconductor fuse including at least one nanowire fuse link, and the fabricating including: forming at least one nanowire, the at least one nanowire including a semiconductor material; and reacting the at least one nanowire with a metal to form the at least one nanowire fuse link of the semiconductor fuse, the at least one nanowire fuse link including a semiconductor-metal alloy. In another aspect, a structure is presented. The structure includes: a semiconductor fuse, the semiconductor fuse including: at least one nanowire fuse link, the at least one nanowire fuse link including a semiconductor-metal alloy.

Abstract: A highly reliable semiconductor device. In a configuration where a precharged source line is discharged to a bit line by establishing electrical continuity between the source line and the bit line through a transistor to read a potential retained at a gate of the transistor, the potential of the bit line is switched in accordance with a change in potential of the source line due to the discharge. With this configuration, the voltage between the source and drain of the transistor can be kept lower than a predetermined voltage by discharge. Accordingly, the source-drain voltage of the transistor can be kept lower than its breakdown voltage, so that the semiconductor device can have high reliability.

Abstract: A semiconductor device structure is provided. The semiconductor device structure includes a semiconductor substrate. The semiconductor device structure includes a dielectric layer positioned on the semiconductor substrate. The dielectric layer has a first recess. The semiconductor device structure includes a conductive structure filling the first recess. The conductive structure includes a first conductive layer and a second conductive layer. The first conductive layer is positioned over an inner wall and a bottom of the first recess. The first conductive layer has a second recess in the first recess. The second conductive layer fills the second recess. The first conductive layer and the second conductive layer include cobalt. The second conductive layer further includes at least one of sulfur, chlorine, boron, phosphorus, or nitrogen.

Abstract: An interconnect structure for use in semiconductor devices and a method for fabricating the same is described. The method includes positioning a substrate in a vacuum processing chamber. The substrate has an exposed copper surface and an exposed low-k dielectric surface. A metal layer is formed over the copper surface but not over the low-k dielectric surface. A metal-based dielectric layer is formed over the metal layer and the low-k dielectric layer.

Abstract: An electrical contact structure for an integrated circuit device is described. A first patterned dielectric layer comprising at least one contact hole, the contact hole including a bottom surface, and sidewalls extending from the bottom surface to a top surface is provided. A tungsten via is disposed within the at least one contact hole, the tungsten via having a bottom surface in contact with a lower layer of the device and a top surface. A selectively deposited metal layer is disposed on the top surface of the tungsten via to repair etch damage.

Abstract: In an LCD driver, in a high voltage resistant MISFET, end portions of a gate electrode run onto electric field relaxing insulation regions. Wires to become source wires or drain wires are formed on an interlayer insulation film of the first layer over the high voltage resistant MISFET. At this moment, when a distance from an interface between a semiconductor substrate and a gate insulation film to an upper portion of the gate electrode is defined as “a”, and a distance from the upper portion of the gate electrode to an upper portion of the interlayer insulation film on which the wires are formed is defined as “b”, a relation of a>b is established. In such a high voltage resistant MISFET structured in this manner, the wires are arranged so as not to be overlapped planarly with the gate electrode of the high voltage resistant MISFET.

Abstract: A semiconductor device has a semiconductor die mounted to a carrier. An encapsulant is deposited over the semiconductor die and carrier. The carrier is removed. A first insulating layer is formed over a portion of the encapsulant within an interconnect site outside a footprint of the semiconductor die. An opening is formed through the first insulating layer within the interconnect site to expose the encapsulant. The opening can be ring-shaped or vias around the interconnect site and within a central region of the interconnect site to expose the encapsulant. A first conductive layer is formed over the first insulating layer to follow a contour of the first insulating layer. A second conductive layer is formed over the first conductive layer and exposed encapsulant. A second insulating layer is formed over the second conductive layer. A bump is formed over the second conductive layer in the interconnect site.

Abstract: A semiconductor package may include a lower substrate with one or more electronic components attached to a surface thereof and an upper substrate with one or more cavities wherein the upper substrate is attached to the lower substrate at a plurality of connection points with the one or more electronic components fitting within a single cavity or a separate cavity for each component that allow the overall form factor of the semiconductor package to remain smaller. The plurality of connection points provide a mechanical and electrical connection between the upper and lower substrate and may include solder joints there between as well as conductive filler particles that create an adhesive reinforcement matrix when compressed for assembly.

Abstract: A semiconductor wafer is provided. The semiconductor wafer includes a base layer having an active region and an edge region. A number of semiconductor devices is formed on the active region. The semiconductor wafer also includes a wafer identification. The wafer identification is formed on the edge region and used for identifying the semiconductor wafer. The semiconductor wafer further includes an alignment mark. The alignment mark is formed on the edge region and is used for performing an alignment process of the semiconductor wafer.

Abstract: Consistent with an example embodiment, a method for preparing integrated circuit (IC) device die from a wafer substrate having a front-side with active devices and a back-side, comprises mounting the front-side of the wafer onto protective foil. A laser is applied to saw lane areas on the backside of the wafer, at a first focus depth to define a modification zone; the modification zone defined at a pre-determined depth within active device boundaries and the active device boundaries defined by the saw lane areas. The protective foil is stretched to separate IC device die from one another and expose active device side-walls. With dry-etching of the active device side-walls, the modification zone is substantially removed.

Abstract: According to one embodiment, there is disclosed a semiconductor device which has a wiring substrate, a semiconductor element mounted on the wiring substrate, a molding resin which seals the semiconductor element, and a shield layer provided on the molding resin, wherein the molding resin has a marking portion by laser irradiation on a surface, and the shield layer is provided on the molding resin having the marking portion.

Abstract: A semiconductor structure includes a substrate, a die disposed over the substrate, and including a die pad disposed over the die and a seal ring disposed at a periphery of the die and electrically connected with the die pad, a polymeric layer disposed over the die, a via extending through the polymeric layer and electrically connected with the die pad, and a molding disposed over the substrate and surrounding the die and the polymeric layer, wherein the seal ring is configured for grounding.

Abstract: A method for manufacturing a semiconductor device is disclosed in which the probability of occurrence of a crack is reduced and in which manufacturing cost is also reduced. An exposure mask used in the method is disclosed. Protrusion portions are formed in intersections of scribe lines in an outermost periphery of a scribe line pattern of a surface protection film of the exposure mask, to thereby stick out toward an outer circumference. In this manner, the probability of occurrence of a crack occurring in a device formation section can be reduced so that a reduction in the manufacturing cost can be achieved.

Abstract: An inventive semiconductor device includes a semiconductor chip having a passivation film, and a sealing resin layer provided over the passivation film for sealing a front side of the semiconductor chip, a groove formed in a periphery of a surface of the semiconductor chip being tapered toward a rear surface of the semiconductor chip, wherein the sealing resin layer is partly disposed in the groove.

Abstract: A mold package being a half-mold type includes: a substrate includes a first face and a second face; an electronic component that is mounted on the first face; and a mold resin that is provided on the first face and seals the first face with the electronic component. The second face is exposed from the mold resin. The mold resin is disposed on the first face so as to seal a sealed portion and to expose a remaining part of the first face as an exposure portion. One side face is provided by an end side face. One side face is provided by a boundary side face. At least a site on a lower end of the boundary side face is provided by an inclined face. In the boundary side face, a site on an upper end side is provided by an other inclined face having a second inclination angle.

Abstract: A semiconductor structure includes a daisy chain adjacent to an edge of a semiconductor chip. The daisy chain includes a plurality of horizontal metal lines distributed in a plurality of metallization layers, wherein the horizontal metal lines are serially connected; a plurality of connecting pads in a same layer and electrically connecting the horizontal metal lines, wherein the connecting pads are physically separated from each other; and a plurality of vertical metal lines, each connecting one of the connecting pads to one of the horizontal metal lines, wherein one of the plurality of connecting pads is connected to one of the plurality of horizontal metal lines by only one of the plurality of vertical metal lines; and a seal ring adjacent and electrically disconnected from the daisy chain.

Abstract: A modularized signal conditioning apparatus system includes at least two slots formed in a coaxial cable. The slots are spaced apart so as to not reduce the measuring performance of the coaxial cable. Slots may be at least 40 mills from one another. In an ESD embodiment, within each slot is an ESD protection component, such as a pair of Shottky diodes coupled between the ground shell and the center conductor of the coaxial cable. Methods of producing modularized signal conditioning apparatus system are also described.

Abstract: Semiconductor packages are provided. The semiconductor packages may include a base film having a top surface and a bottom surface, a circuit pattern disposed on the top surface of the base film and connected to a ground terminal, a via hole penetrating the base film, a lower shielding layer that is electrically connected to the circuit pattern and fills the whole region of the via hole and cover the bottom surface of the base.

Abstract: A method of forming a bond pad structure is provided. The method includes forming a first conductive layer over a substrate and depositing a first dielectric layer over the first conductive layer. The first dielectric layer is patterned to form a contiguous planar path substantially parallel to a top surface of the substrate. Patterning the first dielectric layer includes defining a dielectric region of the first dielectric layer surrounded by a portion of the contiguous planar path, and forming a first via hole in the dielectric region. The contiguous planar path and the via hole are filled with a conductive material. The conductive material in the contiguous planar path forms a second conductive layer, and the contiguous planar path extends from a first lateral side wall of the second conductive layer to a second lateral sidewall of the second conductive layer. A bond pad is formed over the second conductive layer, and the bond pad is electrically connected to the second conductive layer.

Abstract: A semiconductor chip at least includes a row of first electrode pad group, which includes at least one first independent electrode pad and multiple first common electrode pads. The interval between the first independent electrode pad and an electrode pad adjacent thereto is defined as “first pitch”, and the interval between adjacent electrode pads making up the multiple first common electrode pads is defined as “second pitch”. The first pitch is determined to be larger than the second pitch.

Abstract: An electrode connection structure includes: a first electrode of an electrical circuit; and a second electrode of the electrical circuit that is electrically connected to the first electrode. The first and second electrodes are oppositely disposed in direct or indirect contact with each other. A plated lamination is substantially uniformly formed by plating process from a surface of a contact region and opposed surfaces of the first and second electrodes. A void near the surface of the contact region is filled by formation of the plated lamination. Portions of the plated lamination formed from the opposed surfaces of the first and second electrodes in a region other than the contact region are not joined together.

Abstract: A mask unit for depositing a thin layer in a display device. The mask unit includes: a bead mask support which includes a plate; and a bead mask which is placed on the bead mask support.

Abstract: A stacked semiconductor package in an embodiment includes a first semiconductor package including a first circuit board and a first semiconductor element mounted on the first circuit board; and a second semiconductor package including a second circuit board and a second semiconductor element mounted on the second circuit board, the second semiconductor package being stacked on the first semiconductor package. The first semiconductor package further includes a sealing resin sealing the first semiconductor element; a conductive layer located in contact with the sealing resin; and a thermal via connected to the conductive layer and located on the first circuit board.

Abstract: Example methods, apparatus, and products for creating an environmentally protective coating for integrated circuit assemblies are described herein. A preform plastic sheet is places over components of an integrated circuit such that during a reflow process, the preform plastic sheet melts to form a conformal coating over components of the integrated circuit assembly.

Abstract: A thermally-conductive and mechanically-robust bonding method for attaching a metal nanowire (MNW) array to an adjacent surface includes the steps of: removing a template membrane from the MNW; infiltrating the MNW with a bonding material; placing the bonding material on the adjacent surface; bringing an adjacent surface into contact with a top surface of the MNW while the bonding material is bondable; and allowing the bonding material to cool and form a solid bond between the MNW and the adjacent surface. A thermally-conductive and mechanically-robust bonding method for attaching a metal nanowire (MNW) array to an adjacent surface includes the steps of: choosing a bonding material based on a desired bonding process; and without removing the MNW from a template membrane that fills an interstitial volume of the MNW, depositing the bonding material onto a tip of the MNW.

Abstract: Provided is a semiconductor package. The semiconductor package includes: a first die that is a monolithic type die, a driver circuit and a low-side output power device formed in the first die; a second die disposed above the first die, the second die comprising a high-side output power device; and a first connection unit disposed between the first die and the second die.

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: A semiconductor device includes: a substrate including a base member having a main surface and a back surface facing opposite in a thickness direction; a semiconductor element mounted on the main surface of the substrate and having at least one element pad; a wire having a bonding portion bonded to the element pad; and a sealing resin formed on the main surface of the substrate for covering the wire and at least a portion of the semiconductor element. The semiconductor element has an element exposed side surface that faces in a direction crossing the thickness direction of the substrate and is exposed from the sealing resin.

Abstract: A system-in-package module includes a non-memory chip, a bundled memory, and an encapsulation package material. The non-memory chip has a plurality of pads. The bundled memory includes a first memory die and a second memory die side-by-side formed over a substrate, wherein the first memory die includes a first group of pads and the second memory die includes a second group of pads. The encapsulation package material encloses the non-memory chip and the bundled memory, and the non-memory chip is electronically coupling with the bundled memory through the plurality of pads, the first and the second group of pads. The first group of pads corresponds to the second group of pads by rotating a predetermined degree or by mirror mapping.

Abstract: Method comprising steps as follows: a) depositing a meltable ball on a first conducting zone located in a blind hole formed on a first face of a first support, b) assembling the first support with a second support by transfer of the meltable ball on a second conducting zone, the transfer also being made by thermo-compression so as to compress the ball, the compressed ball being held at a distance from the side walls of the blind hole.

Abstract: A stacked semiconductor package has a first semiconductor package including a first package substrate and a first semiconductor chip mounted on the first package substrate, a second semiconductor package including a second package substrate and a second semiconductor chip mounted on the second package substrate, and a plurality of connections electrically connecting the first and second semiconductor packages. The connections are disposed on an outer region of the first package substrate outside the first semiconductor chip. The connections are disposed along opposite first longer sides and opposite shorter second sides of the first package substrate. The heights of those connections disposed along each longer first side gradually vary from a central to an outer region (i.e., the ends) of the longer first side.

Abstract: Alignment of a first micro-electronic component to a receiving surface of a second micro-electronic component is realized by a capillary force-induced self-alignment, combined with an electrostatic alignment. The latter is accomplished by providing at least one first electrical conductor line along the periphery of the first component, and at least one second electrical conductor along the periphery of the location on the receiving surface of the second component onto which the component is to be placed. The contact areas surrounded by the conductor lines are covered with a wetting layer. The electrical conductor lines may be embedded in a strip of anti-wetting material that runs along the peripheries to create a wettability contrast. The wettability contrast helps to maintain a drop of alignment liquid between the contact areas so as to obtain self-alignment by capillary force.

Abstract: A chip package including a semiconductor substrate is provided. A recess is in the semiconductor substrate and adjoins a side edge of the semiconductor substrate, wherein the semiconductor substrate has at least one spacer protruding from the bottom of the recess. A conducting layer is disposed on the semiconductor substrate and extends into the recess.

Abstract: A semiconductor device has a first substrate. A conductive layer is formed over the first substrate. A first cavity is formed through the first substrate and extending to the conductive layer. A first semiconductor die including a plurality of first interconnect structures is disposed in the first cavity. A second substrate is disposed over the first substrate. A second cavity is formed through second substrate. A second semiconductor die including a plurality of second interconnect structures is disposed in the second cavity. A discrete device or third semiconductor die is disposed over the second semiconductor die. A plurality of third interconnect structures is formed between the second substrate and discrete device or third semiconductor die. The first, second, and third interconnect structures are reflowed simultaneously. An encapsulant is deposited over and around the first semiconductor die, the second semiconductor die, and the discrete device or third semiconductor die.

Abstract: A semiconductor device has a plurality of conductive vias formed through the semiconductor die with a first insulating layer around the conductive vias. A recess is formed in the first insulating layer around the conductive vias by LDA. A portion of the semiconductor wafer is removed by LDA after forming the recess in the first insulating layer so that the conductive vias extend above a surface of the semiconductor wafer. The first insulating layer extends to the surface of the semiconductor wafer or above the surface of the semiconductor wafer. A second insulating layer is formed over the surface of the semiconductor wafer and conductive vias. A first portion of the second insulating layer is removed by LDA, while leaving a second portion of the second insulating layer over the surface of the semiconductor wafer around the conductive vias. An electroless plated bump is formed over the conductive vias.

Abstract: An embodiment package includes a first fan-out tier having a first device die, a molding compound extending along sidewalls of the first device die, and a through intervia (TIV) extending through the molding compound. One or more first fan-out redistribution layers (RDLs) are disposed over the first fan-out tier and bonded to the first device die. A second fan-out tier having a second device die is disposed over the one or more first fan-out RDLs. The one or more first fan-out RDLs electrically connects the first and second device dies. The TIV electrically connects the one or more first fan-out RDLs to one or more second fan-out RDLs. The package further includes a plurality of external connectors at least partially disposed in the one or more second fan-out RDLs. The plurality of external connectors are further disposed on conductive features in the one or more second fan-out RDLs.

Abstract: In some embodiments, a semiconductor device package may include a semiconductor device package on package assembly. The package on package assembly may include a first package, a second package, and a shield. The first package may include a first surface, a second surface substantially opposite the first surface, a first die, and a first set of electrical conductors coupled to the first surface and configured to electrically connect the package on package assembly. The second package may include a third surface and a fourth surface substantially opposite the third surface, and a second die. The third surface may be coupled to the second surface. The first package may be electrically coupled to the second package. The shield may be applied to the fourth surface of the semiconductor device package assembly. In some embodiments, the shield may transfer, during use, heat from the first die.

Abstract: A chip-stacked semiconductor package includes a first chip having a first front surface, a first back surface, and a first connection member on the first front surface, the first back surface being opposite to the first front surface; a second chip having a second front surface, a second back surface, a second connection member and a first through-silicon via (TSV) electrically connected to the second connection member, the second back surface opposite to the second front surface, and the second connection member on the second front face; and a first sealing member between the first front surface and the second front surface, the first sealing member filling a space between the first connection member and the second connection member, the first connection member of the first chip and the second connection member of the second chip being symmetric with respect to each other.

Abstract: Provided is a semiconductor package and a method of making same, including a first package substrate; a first semiconductor chip mounted on the first package substrate and having a first pad and a second pad, wherein the first pad is provided on a top of the first semiconductor chip and the second pad is provided on a bottom of the first semiconductor chip, the bottom being an opposite surface of the top; and a clad metal provided on the first pad and electrically connecting the first semiconductor chip to one of a second semiconductor chip and second package substrate provided on the top of the first semiconductor chip.

Abstract: In a microelectronic package, a first wire bond wire is coupled to an upper surface of a substrate. A first bond mass is coupled to another end of the first wire bond wire. A second wire bond wire is coupled to the upper surface. A second bond mass is coupled to another end of the second wire bond wire. The first and second wire bond wires laterally jut out horizontally away from the upper surface of the substrate for at least a distance of approximately 2 to 3 times a diameter of both the first wire bond wire and the second wire bond wire. The first wire bond wire and the second wire bond wire are horizontal for the distance with respect to being co-planar with the upper surface within +/?10 degrees.

Abstract: Embodiments of the present disclosure are directed to integrated circuit (IC) package assemblies with magnetic contacts, as well as corresponding fabrication methods and systems incorporating such magnetic contacts. A first IC substrate may have a first magnet coupled with a first electrical routing feature. A second IC substrate may have a second magnet coupled with a second electrical routing feature. The magnets may be embedded in the IC substrates and/or electrical routing features. The magnets may generate a magnetic field that extends across a gap between the first and second electrical routing features. Electrically conductive magnetic particles may be applied to one or both of the IC substrates to form a magnetic interconnect structure that extends across the gap. In some embodiments, magnetic contacts may be demagnetized by heating the magnets to a corresponding partial demagnetization temperature (PDT) or Curie temperature. Other embodiments may be described and/or claimed.