Abstract: A die stack package is provided and includes a substrate, a stack of computing components, at least one thermal plate, which is thermally communicative with the stack and a lid supported on the substrate to surround the stack and the at least one thermal plate to thereby define a first heat transfer path extending from one of the computing components to the lid via the at least one thermal plate and a fin coupled to a surface of the lid and the at least one thermal plate, and a second heat transfer path extending from the one of the computing components to the lid surface without passing through the at least one thermal plate.

Abstract: A package structure includes a substrate, a first die and at least one second die. The substrate includes a first pair of parallel edges and a second pair of parallel edges. The first die is mounted over the substrate. The first die includes a third pair of parallel edges and a fourth pair of parallel edges, wherein the third pair of parallel edges and the fourth pair of parallel edges are not parallel to the first pair of parallel edges and the second pair of parallel edges, respectively. The at least one second die is mounted over the first die.

Abstract: A lead frame strip includes an array of sites arranged in at least one row connected to two exterior side rails which traverse the lead frame strip on two opposite sides. Each of the sites is further connected to the two exterior side rails by subrails which extend between the two exterior side rails. Interior side rails extend between the subrails having a length dimension oriented along a first direction. The interior side rails include at least one punch degating aperture having an aperture length oriented along the first direction, wherein a total of the aperture length along the interior side rails is greater than or equal to the die pad length.

Abstract: In a method of fabricating an integrated circuit device having a three-dimensional stacked structured, the step of fixing many chip-shaped semiconductor circuits to a support substrate or a circuit layer with a predetermined layout can be performed easily and efficiently with a desired accuracy. Temporary adhesion portions 12b of semiconductor chips 13 are temporarily adhered to corresponding temporary adhesion regions 72a of a carrier substrate 73a by way of water films 81. The carrier substrate 73a is then pressed toward a support substrate or a desired circuit layer, thereby contacting connecting portions 12 of the chips 13 on the carrier substrate 73a with corresponding predetermined positions on the support substrate or a circuit layer. Thereafter, by fixing the connecting portions 12 to the predetermined positions, the chips 13 are attached to the support substrate or the circuit layer with a desired layout.

Abstract: The present invention provides a method for packaging semiconductor device which is using more than once reflow processes to heat the solder ball to prevent the deformation of solder ball, so that the yield of the manufacturing process can be increased and the reliability of the semiconductor device can be increased.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a package carrier; mounting an integrated circuit device to the package carrier; mounting an embeddable conductive structure, having a non-horizontal portion between a lower portion and an elevated portion and a hole, to the integrated circuit device with the lower portion over the integrated circuit device; mounting an interposer to the lower portion and below the elevated portion; and forming an encapsulation having a recess exposing the interposer and the elevated portion.

Abstract: Various semiconductor chip input/output structures and methods of making the same are disclosed. In one aspect, a method of manufacturing is provided that includes providing a semiconductor chip that has a first conductor pad and a passivation structure. A second conductor pad is fabricated around but not in physical contact with the first conductor pad to leave a gap. The second conductor pad is adapted to protect a portion of the passivation structure.

Abstract: A soldering method of soldering first and second members includes shooting a laser light to at least one part of an outer peripheral portion surrounding a soldering-target region of the first member thereby to form an oxide film, and bonding the second member with the soldering-target region through a solder. According to the method, the solder resist is never exfoliated even after cleaning with chemicals for removing flux residues contained in solder.

Abstract: A semiconductor device in accordance with an embodiment comprises a semiconductor chip; a die pad having a chip mount surface for mounting the semiconductor chip; first leads electrically connected to the semiconductor chip; a thermosetting resin part for securing end parts of the first leads to the die pad; and a thermoplastic resin part for sealing the semiconductor chip, the die pad, and the thermosetting resin part.

Abstract: A semiconductor device includes a semiconductor chip and a base plate coupled to the semiconductor chip. The base plate includes an upper portion and a lower portion. The upper portion has a bottom surface intersecting a sidewall of the lower portion. The semiconductor device includes a cooling element coupled to the base plate. The cooling element has a first surface directly contacting the bottom surface of the upper portion of the base plate, a second surface directly contacting the sidewall of the lower portion of the base plate, and a third surface parallel to the first surface and aligned with a bottom surface of the lower portion of the base plate.

Abstract: A method of manufacturing of an integrated circuit packaging system includes: providing a bottom package in a cavity in a central region of the bottom package having inter-package interconnects in the cavity; forming a vent on an inter-package connection side of the bottom package from an exterior of the bottom package to the cavity; mounting a top package on the inter-package interconnects; and applying an underfill through the vent and into the cavity.

Abstract: A method of forming an integrated circuit structure, the method includes providing a semiconductor substrate; forming a dielectric layer over the semiconductor substrate; forming an opening in the dielectric layer; forming a seed layer in the opening; forming a copper line on the seed layer, wherein at least one of the seed layer and the copper line includes an alloying material; and forming an etch stop layer on the copper line.

Abstract: A method for manufacturing a semiconductor device, includes: placing a seal layer including a connection conductive film on the surface so that the connection conductive film is in contact with an electrode of a semiconductor element and a lead; electrically coupling the electrode and the lead through the connection conductive film; and sealing the semiconductor element by the seal layer.

Abstract: The semiconductor assembly includes a first subassembly having a heat sink. Solder material is disposed on the exposed portion of a first surface of heat sink. A power semiconductor die is located on the first surface of the heat sink and is thermally coupled thereto by the solder material. A packaging patterned polymer layer is disposed on a second surface of the heat sink opposing the first surface and defines an interior surface portion of the heat sink. A semiconductor package is provided in which the first subassembly, solder material and die are located such that the interior surface portion of the second surface of the heat sink is not enclosed by the semiconductor package.

Abstract: A semiconductor device includes a semiconductor substrate having first and second surfaces opposite each other, the first surface being an active surface by provided with an electronic element thereon, a pad electrode formed to be connected to the electronic element in a peripheral portion of the electronic element on the active surface, a first opening extending from the second surface toward the pad electrode so as not to reach the first surface of the semiconductor substrate, a second opening, formed to reach the pad electrode from a bottom surface of the first opening, having a diameter smaller than that of the first opening, an insulating layer formed to cover sidewall surfaces of the first opening and the second opening, and a conductive layer formed, inside of the insulating layer, to cover at least an inner wall surface of the insulating layer and a bottom surface of the second opening.

Abstract: A plastic package (100) in which a semiconductor chip (101) is adhesively (102) attached to a metal stripe (110a) having an agglomerate structure, and electrically connected to bondable and solderable metal stripes (120) having particulate structures; metal stripes (120) are touching metal stripes (110b) of agglomerate structure to form vertical stacks (150); coats of solder (140) are welded to the agglomerate metal stripes (100a and 110b).

Abstract: Wafer level embedded and stacked die power system-in-package semiconductor devices, and methods for making and using the same, are described. The methods include placing a first side of a substrate frame, which includes through cavity and an adjacent via, on a carrier. A first side of a component selected from an active device and a passive device can be placed on the carrier, within the cavity. A perimeter of the cavity can be attached to a perimeter of the component. Material at a second side of the substrate frame can be removed so the via extends from the frame's first side to the frame's second side. The substrate frame and component can then be removed from the carrier so that routing can be distributed between the first side of the frame and the first side of the component to electrically connect the component with the via. Other embodiments are described.

Abstract: A multilayer wiring substrate has an upper surface with multiple bonding leads and a lower surface with multiple lands. Multiple wiring layers and insulating layers are alternately formed on the upper surface side and on the lower surface side of the core material of the wiring substrate. The bonding leads are formed of part of the uppermost wiring layer and the lands are formed of part of the lowermost wiring layer. The insulating layers include second insulating layers containing fiber and resin and third insulating layers smaller in fiber content than the second insulating layers. The second insulating layers are formed on the upper and lower surface sides of the core material. The third insulating layers are formed on the upper and lower surface sides of the core material with the second insulating layers in-between. The uppermost and lowermost wiring layers are formed over the third insulating layers.

Abstract: A method, apparatus and system with an autonomic, self-healing polymer capable of slowing crack propagation within the polymer and slowing delamination at a material interface.

Abstract: A structured glass wafer for packaging a microelectromechanical-system (MEMS) wafer. The structured glass wafer includes a sheet of glass, and an access hole. The sheet of glass has a first side and a second side, and is configured to provide a protective covering for MEMS devices. The access hole extends through the sheet of glass from the first side to the second side of the sheet of glass, and is configured to provide access to a group of electrical contacts of a group of MEMS devices. A packaged MEMS wafer including the structured glass wafer, and a method for fabricating a packaged MEMS wafer are also provided.

Abstract: A semiconductor device 100 has such a structure that a semiconductor chip 110 is flip-chip mounted on a wiring board 120. The wiring board 120 has a multilayer structure in which a plurality of wiring layers and a plurality of insulating layers are arranged, and has a structure in which insulating layers of a first layer 122, a second layer 124, a third layer 126 and a fourth layer 128 are provided. The first layer 122 has a first insulating layer 121 and a second insulating layer 123. A protruded portion 132 which is protruded in a radial direction (a circumferential direction) from an outer periphery at one surface side of a first electrode pad 130 is formed on a whole periphery over a boundary surface between the first insulating layer 121 and the second insulating layer 123.

Abstract: A method for connecting substrates is provided. The method includes the steps of: preparing a first wiring substrate having a first substrate including a first region and a second region which are provided with a first metal wire, wherein an area ratio between the first region and the first metal wires in the first region is different from an area ratio between the second region and the first metal wire in the second region; heating the first wiring substrate to bend the first wiring substrate; and electrically connecting a third wiring on a third substrate to the first metal wire provided on the first wiring substrate, thereby mounting the first wiring substrate on the third substrate in a manner that the first surface of the first substrate is nonparallel to the first surface of the third substrate.

Abstract: This publication discloses a method for manufacturing a circuit-board structure.1. The structure comprises a conductor pattern (3) and at least one component (6), which is surrounded by an insulating-material layer (10), attached to it by means of a contact bump (5). According to the invention, the contact bumps (5) are made on the surface of the conductor pattern (3), before the component (6) is attached to the conductor pattern (3) by means of the contact bump (5). After attaching, the component (6) is surrounded with an insulating-material layer (10).

Abstract: A method for making an electronic device includes forming an interconnect layer stack on a rigid wafer substrate having a plurality of patterned electrical conductor layers, a dielectric layer between adjacent patterned electrical conductor layers, and at least one solder pad on an uppermost patterned electrical conductor layer. An LCP solder mask having at least one aperture therein alignable with the at least one solder pad is formed. The LCP solder mask and interconnect layer stack are aligned and laminated together. Solder is positioned in the at least one aperture. At least one circuit component is attached to the at least one solder pad using the solder.

Abstract: A method of making an electronic device includes forming a circuit layer on a liquid crystal polymer (LCP) substrate and having at least one solder pad. The method also includes forming an LCP solder mask having at least one aperture therein alignable with the at least one solder pad. The method further includes aligning and laminating the LCP solder mask and the LCP substrate together, then positioning solder paste in the at least one aperture. At least one circuit component may then be attached to the at least one solder pad using the solder paste.

Abstract: A method is for making an electronic device and includes forming an interconnect layer stack on a sacrificial substrate and having a plurality of patterned electrical conductor layers, and a dielectric layer between adjacent patterned electrical conductor layers. The method also includes laminating and electrically joining through an intermetallic bond a liquid crystal polymer (LCP) substrate to the interconnect layer stack on a side thereof opposite the sacrificial substrate. The method further includes removing the sacrificial substrate to expose a lowermost patterned electrical conductor layer, and electrically coupling at least one first device to the lowermost patterned electrical conductor layer.

Abstract: A method for manufacturing a semiconductor package system includes: providing a leadframe, having an open center, with leads adjacent to a peripheral edge of the leadframe; making a die support pad, formed without tie bars, separately from the leadframe; providing a coverlay tape for positioning the support pad centered within the leadframe; attaching a semiconductor die to the die support pad through a die attach adhesive, the semiconductor die being spaced from the leads; and connecting a bonding pad on the semiconductor die to one of the leads using a bonding wire.

Abstract: An arrangement for improving the cooling efficiency of semiconductor chips. One embodiment is to construct a vapor chamber with one compliant surface for improving the efficiency of transferring heat from a semiconductor chip to the vapor chamber, and another embodiment is to construct a vapor chamber with the chip substrate such that the chips are embedded inside the vapor chamber. One surface of the vapor chamber has a flexible structure to enable the surface of the vapor chamber to be compliant with the surface of a chip or a heat sink device.

Abstract: A semiconductor device and an assembling method thereof are provided. The semiconductor device includes a chip, a carrier, a plurality of first conductive elements and a plurality of second conductive elements. The chip has a plurality of first pads. The carrier has a plurality of second pads. The second pads correspond to the first pads. Each first conductive element is disposed between one of the first pads and one of the second pads. Each second conductive element is disposed between one of the first pads and one of the second pads. A volume ratio of intermetallic compound of the second conductive elements is greater than a volume ratio of intermetallic compound of the first conductive elements.

Abstract: A semiconductor device according to the present disclosure includes: a plate (13) having a through hole (15); a metal column (16) fixed to the through hole with an insulating member (17) interposed therebetween, and having a projection projecting from the upper surface of the plate; a semiconductor element (12) fixed to the projection; a lead frame (11) electrically connected to the semiconductor element; and a package (14) covering the semiconductor element, and also covering at least part of each of the plate, the metal column, and the lead frame. The lower surface (13b) of the plate is exposed from the package.

Abstract: A flexible film interposer for stacking a flip chip semiconductor die onto a second (bottom) semiconductor die, semiconductor devices and stacked die assemblies that incorporate the flexible film interposer, and methods of fabricating the devices and assemblies are provided. The incorporation of the flexible film interposer achieves densely packaged semiconductor devices, without the need for a redistribution layer (RDL).

Abstract: The device of this invention includes a semiconductor die attached to a bare copper lead frame and electrically coupled to a lead by a metal wire coated with a metallic material. The device would function similarly to devices where the lead frames were coated with other metallic materials, but at lower costs because instead of plating the lead frame the wire is plated. The wire can be either gold or aluminum. When the wire is gold, the coating may be silver or other suitable metallic materials. When the wire is aluminum, the coating may be nickel, palladium, or other suitable metals.

Abstract: A semiconductor module according to one embodiment includes a semiconductor chip, an insulating substrate, a case, an electrode, a busbar and a busbar support body. The semiconductor chip is mounted on the insulating substrate. The insulating substrate is housed inside the case. The electrode is disposed in the case and is electrically connected to the semiconductor chip. The electrode is supported on an electrode support section of the case. The busbar is bonded to the electrode and is led out of the case. The busbar support body holds the busbar and is mounted on the case.

Abstract: Semiconductor devices and methods of manufacturing semiconductor devices. One example of a method of fabricating a semiconductor device comprises forming a conductive feature extending through a semiconductor substrate such that the conductive feature has a first end and a second end opposite the first end, and wherein the second end projects outwardly from a surface of the substrate. The method can further include forming a dielectric layer over the surface of the substrate and the second end of the conductive feature such that the dielectric layer has an original thickness. The method can also include removing a portion of the dielectric layer to an intermediate depth less than the original thickness such that at least a portion of the second end of the conductive feature is exposed.

Abstract: A method of making a stackable semiconductor assembly that includes a semiconductor device, a heat spreader, an adhesive, a terminal, a plated through-hole and build-up circuitry is disclosed. The heat spreader includes a bump, a base and a flange. The bump defines a cavity. The semiconductor device is mounted on the bump at the cavity, electrically connected to the build-up circuitry and thermally connected to the bump. The bump extends from the base into an opening in the adhesive, the base extends vertically from the bump opposite the cavity and the flange extends laterally from the bump at the cavity entrance. The build-up circuitry provides signal routing for the semiconductor device. The plated through-hole provides signal routing between the build-up circuitry and the terminal. The heat spreader provides heat dissipation for the semiconductor device.

Abstract: A semiconductor device includes: a substrate including an electrode pad on a surface; a semiconductor chip placed on the substrate so as to be electrically connected to the electrode pad; a first resin layer which is formed on the substrate and is also filled between the substrate and the semiconductor chip; and a second resin layer, laminated on the first resin layer, which has an elastic modulus larger than that of the first resin layer.

Abstract: A micromechanical component having at least two caverns is provided, the caverns being delimited by the micromechanical component and a cap, and the caverns having different internal atmospheric pressures. The micromechanical component and cap are hermetically joined to one another at a first specifiable atmospheric pressure, then an access to at least one cavern is produced, and subsequently the access is hermetically closed off at a second specifiable atmospheric pressure.

Abstract: An apparatus and method of manufacture may be provided for a package that can be coupled to a common heat sink without external electrical isolation. The apparatus, for example, can include a semi-conductor die comprising at least one electronic device. The apparatus can also include a frame on which a bottom side of the die is mounted, a bottom side of the frame being configured to attach to a printed circuit board. The apparatus can further include a high thermal conductivity resin molded onto a top side of the die.

Abstract: An improved stacked-die package includes an interposer which improves the manufacturability of the package. A semiconductor package includes a package substrate having a plurality of bond pads; a first semiconductor device mounted on the package substrate, the first semiconductor device having a plurality of bond pads provided thereon; an interposer mounted on the first semiconductor device, the interposer having a first interposer bond pad and a second interposer bond pad, wherein the first and second interposer bond pads are electrically coupled; a second semiconductor device mounted on the interposer, the second semiconductor device having a plurality of bond pads provided thereon; a first bond wire connected to one of the plurality of bond pads on said first semiconductor and to the first interposer bond pad; and a second bond wire connected to the second interposer bond pad and to one of the plurality of bond pads on the semiconductor device.

Abstract: An electronic component device includes a substrate, an electrode post made of a metal material, provide to stand on the substrate, and an electronic component whose connection electrode is connected to the electrode post, wherein the connection electrode of the electronic component and the electrode post are joined by an alloy layer including a metal which is different from the metal material of the electrode post.

Abstract: A module having a discrete passive element and a semiconductor device, and method of forming the same. In one embodiment, the module includes a patterned leadframe, a discrete passive element mounted on an upper surface of the leadframe, and a thermally conductive, electrically insulating material formed on an upper surface of the discrete passive element. The module also includes a semiconductor device bonded to an upper surface of the thermally conductive, electrically insulating material.

Abstract: It is aimed at improving the reliability of a semiconductor device. In a POP having an upper package stacked on a lower package, an opening of a first solder resist film in a first region between a first group of lands arranged at the periphery of an front surface of a wiring substrate of the lower package and a second group of lands arranged in a central part is filled with a second solder resist film, and thereby the formation of a starting point of cracks in the opening becomes unlikely to suppress occurrence of cracks and improve the reliability of the POP.

Abstract: A semiconductor package may include a substrate with a first surface over which bond fingers are formed. At least two semiconductor chips may be stacked on the first surface of the substrate and each chip may have via holes. The semiconductor chips may be stacked such that the respective via holes expose the respective bond fingers of the substrate. Through electrodes may be formed in the via holes. The through electrodes may comprise carbon nanotubes grown from the exposed bond fingers of the substrate, where the through electrodes may be electrically connected with the semiconductor chips.

Abstract: Microelectronic devices and methods for manufacturing microelectronic devices are described herein. An embodiment of one such method includes attaching a plurality of singulated microelectronic dies to a removable support member with an active side of the individual dies facing toward the support member, depositing a flowable material onto the dies and a portion of the removable support member such that the flowable material covers a back side of the individual dies and is disposed between adjacent dies, and removing the support member from the active sides of the dies.

Abstract: The invention relates to a method for producing chip elements provided with a groove, comprising the following steps: on an interconnect substrate, providing a conductive track arranged to connect a contact area of an active surface of a chip to an area corresponding to a first wall of the groove; growing a contact bump by electrodeposition on the conductive track at the level of the area corresponding to the first wall of the groove; assembling the chip on the substrate via its active surface so that a side wall of the chip forms the bottom of the groove; machining the chip via its rear surface in parallel to the substrate while measuring the distance between the rear surface of the chip and the contact bump; stopping machining when the measured distance reaches a required value; and assembling by bonding a plate to the rear surface of the chip so as to form a second wall of the groove.

Abstract: A semiconductor module system includes a module substrate and first and second semiconductor components stacked on the module substrate. The stacked semiconductor components include through wire interconnects that form an internal signal transmission system for the module system. Each through wire interconnect includes a via, a wire in the via and first and second contacts on the wire.

Abstract: A component includes a first semiconductor chip attached to a first carrier and second semiconductor chip attached to a second carrier. The first carrier has a first extension, which forms a first external contact element. The second carrier has a second extension, which forms a second external contact element. The first and the second carriers are arranged in such a way that the first and the second extension point in different directions.

Abstract: An environment-resistant module which provides both thermal and vibration isolation for a packaged micromachined or MEMS device is disclosed. A microplatform and a support structure for the microplatform provide the thermal and vibration isolation. The package is both hermetic and vacuum compatible and provides vertical feedthroughs for signal transfer. A micromachined or MEMS device transfer method is also disclosed that can handle a wide variety of individual micromachined or MEMS dies or wafers, in either a hybrid or integrated fashion. The module simultaneously provides both thermal and vibration isolation for the MEMS device using the microplatform and the support structure which may be fabricated from a thin glass wafer that is patterned to create crab-leg shaped suspension tethers or beams.

Abstract: A rear surface opposite to one plane of a die pad is formed to be exposed from one plane of a sealing resin. In addition, a concave portion disposed to be parallel with at least a first side of an outermost edge of a central structure and a second side adjacent to the first side, respectively, is formed in the one plane of the sealing resin. Here, a depth of the concave portion is equal to or greater than a height of the outermost edge of the central structure.

Abstract: A circuit board has a curved portion provided in at least one side of an external shape thereof. An external connecting terminal is provided on a first main surface of the circuit board. A semiconductor element is mounted on a second main surface of the circuit board. A first wiring network is provided in a region except the terminal region on the first main surface. A second wiring network is provided on the second main surface. Distance from the side including the curved portion to the first wiring network is larger than distance from at least one of the other sides to the first wiring networks, and distance from the side including the curved portion to the second wiring network is larger than distance from at least one of the other sides to the second wiring networks.