Abstract: An optoelectronic (OE) package or system and method for fabrication is disclosed which includes a silicon layer with wiring. The silicon layer has an optical via for allowing light to pass therethrough. An optical coupling layer is bonded to the silicon layer, and the optical coupling layer includes a plurality of microlenses for focusing and or collimating the light through the optical via. A plurality of OE elements are coupled to the silicon layer and electrically communicating with the wiring. At least one of the OE elements positioned in optical alignment with the optical via for receiving the light. A carrier is interposed between electrical interconnect elements. The carrier is positioned between the wiring of the silicon layer and a circuit board and the carrier is electrically connecting first interconnect elements connected to the wiring of the silicon layer and second interconnect elements connected to the circuit board.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a substrate; attaching a flip chip to the substrate; attaching a heat slug to the substrate and the flip chip; and forming a moldable underfill having a top underfill surface on the substrate, the flip chip, and the heat slug, the moldable underfill having a characteristic of being liquid at room temperature and the top underfill surface over the flip chip.

Abstract: An electronic control unit includes a substrate, a semiconductor module, a heat storage body, an insulator, and a heat sink. The substrate includes a wiring and a land. The semiconductor module includes a semiconductor chip working as a switching element, a terminal electrically coupled with the semiconductor chip and the wiring, a molded resin sealing the semiconductor chip and the terminal, and a heat radiation plate having a surface exposed from the molded resin and transferring heat generated at the semiconductor chip. The heat storage body has a heat capacity required to store the heat generated at the semiconductor chip. The heat storage body is coupled with the heat radiation plate. The insulator is in contact with the heat storage body or the semiconductor module. The heat sink is in contact with the insulator.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a base substrate; attaching a package stack assembly, having a contact pad, on the base substrate; applying an encapsulation having a cavity with a tapered side directly over the package stack assembly, the contact pad exposed in the cavity; attaching a recessed circuitry unit in the cavity and on the contact pad, a chamber of the cavity formed by the recessed circuitry unit and the tapered side of the cavity; and mounting a thermal structure over the recessed circuitry unit, the cavity, and the encapsulation.

Abstract: Stacked semiconductor chips. One embodiment provides a device having a first body. A first power semiconductor chip and first external contact elements is provides. A second body includes a second semiconductor chip and second external contact elements. The second body is placed over the first body. The first external contact elements and the second external contact elements define a first plane.

Abstract: A semiconductor device includes: a substrate; a semiconductor chip with a surface facing down mounted on the substrate; a reinforcement material provided on the substrate in a peripheral region of a region on which the semiconductor chip is mounted; and a heat sink coupled to the semiconductor chip via a highly thermally conductive material. The heat sink is disposed on the semiconductor chip and the reinforcement material by being coupled to the reinforcement material via an adhesive material, and is provided with an uneven area on a side coupled to the reinforcement material.

Abstract: A thermal interface material includes a thermally conductive metal matrix and coarse polymeric particles dispersed therein. The composite can be used for both TIM1 and TIM2 applications in electronic devices.

Abstract: A circuit substrate has one or more active components and a plurality of passive circuit elements on a first surface. An active semiconductor device has a substrate with layers of material and a plurality of terminals. The active semiconductor device is flip-chip mounted on the circuit substrate and at least one of the terminals of the device is electrically connected to an active component on the circuit substrate. The active components on the substrate and the flip-chip mounted active semiconductor device, in combination with passive circuit elements, form preamplifiers and an output amplifier respectively. In a power switching configuration, the circuit substrate has logic control circuits on a first surface. A semiconductor transistor flip-chip mounted on the circuit substrate is electrically connected to the control circuits on the first surface to thereby control the on and off switching of the flip-chip mounted device.

Abstract: A semiconductor element cooling apparatus includes: a first member whose first surface on which a semiconductor element is mounted, and whose second surface has fins that define coolant flow paths, and that extend in a first direction, and that stand from the second surface to a predetermined height, and that are spaced from each other by predetermined intervals; and a second member that defines the coolant flow paths that extend in the first direction. The fins have grooves which extend in a second direction that intersects the first direction, and which have a depth that extends from the distal end side of the fins toward the second surface. The depth of the grooves is smaller than the height of the fins. A protrusion-forming member is disposed in the grooves, and extends across adjacent fins, and forms protrusions in the coolant flow paths defined by the adjacent fins.

Abstract: A semiconductor wafer contains a plurality of first semiconductor die. The semiconductor wafer is mounted to a carrier. A channel is formed through the semiconductor wafer to separate the first semiconductor die. A second semiconductor die is mounted to the first semiconductor die. An encapsulant is deposited over the carrier and first semiconductor die and into the channel while a side portion and surface portion of the second semiconductor die remain exposed from the encapsulant. A first conductive via is formed through the encapsulant in the channel. A second conductive via is formed through the encapsulant over a contact pad of the first semiconductor die. A conductive layer is formed over the encapsulant between the first and second conductive vias. An insulating layer is formed over the conductive layer and encapsulant. The carrier is removed. An interconnect structure is formed over the first conductive via.

Abstract: A package-on-package (PoP) device is provided. The device includes a first package with a first chip mounted on a first substrate, a heat spreader stacked on the first package, the heat spreader in thermal contact with the first chip, and a second package stacked on the heat spreader. In an embodiment, the heat spreader is formed using carbon fibers to provide good lateral thermal conductivity. In an embodiment, ends of the heat spreader project beyond a periphery of the first and second packages.

Abstract: The heat-release properties of semiconductor device are to be improved and the reliability thereof is to be improved. The semiconductor device has a wiring substrate, a heat-releasing plate having a convex part inserted into a through-hole of the wiring substrate, a semiconductor chip mounted over the convex part of the heat-releasing plate, and a bonding wire coupling an electrode pad of the semiconductor chip with a bonding lead of the wiring substrate, and further has a sealing portion covering a portion of an upper surface of the wiring substrate, a sealing portion covering a portion of a lower surface of the wiring substrate including the semiconductor chip and the bonding wire, and a solder ball placed over a lower surface of the wiring substrate.

Abstract: A wafer stacked semiconductor package (WSP) having a vertical heat emission path and a method of fabricating the same are provided. The WSP comprises a substrate on which semiconductor chips are mounted; a plurality of semiconductor chips stacked vertically on the substrate; a cooling through-hole formed vertically in the plurality of semiconductor chips, and sealed; micro holes formed on the circumference of the cooling through-hole; and coolant filling the inside of the cooling through-hole. Accordingly, the WSP reduces a temperature difference between the semiconductor chips and quickly dissipates the heat generated by the stacked semiconductor chips.

Abstract: A semiconductor device and a method of producing the same, wherein a joining member and a joined member are bonded by means of brazing in a way such that no voids are left inside the joining layer. The semiconductor device comprises a joined member and a joining member which is joined to the joined member by means of brazing. The joined member is provided with a through hole which is open on the joining surface with the joining member, and a path communicating with the through hole is provided on at least one of the joining surface of the joining member with the joined member or the joining surface of the member with the joining member.

Abstract: Stress regulated semiconductor devices and associated methods are provided. In one aspect, for example, a stress regulated semiconductor device can include a semiconductor layer, a stress regulating interface layer including a carbon layer formed on the semiconductor layer, and a heat spreader coupled to the carbon layer opposite the semiconductor layer. The stress regulating interface layer is operable to reduce the coefficient of thermal expansion difference between the semiconductor layer and the heat spreader to less than or equal to about 10 ppm/° C.

Abstract: Some exemplary embodiments of high voltage cascaded III-nitride semiconductor package with an etched leadframe have been disclosed. One exemplary embodiment comprises a III-nitride transistor having an anode of a diode stacked over a source of the III-nitride transistor, and a leadframe that is etched to form a first leadframe paddle portion coupled to a gate of the III-nitride transistor and the anode of the diode, and a second leadframe paddle portion coupled to a drain of the III-nitride transistor. The leadframe paddle portions enable the package to be surface mountable. In this manner, reduced package footprint, improved surge current capability, and higher performance may be achieved compared to conventional wire bonded packages. Furthermore, since multiple packages may be assembled at a time, high integration and cost savings may be achieved compared to conventional methods requiring individual package processing and externally sourced parts.

Abstract: A chip on film (COF) type semiconductor package is provided. The chip on film (COF) type semiconductor package includes a film, a plurality of leads formed on a surface of the film, a chip adhered to ends of the leads, an underfill layer filled within a space between the chip and the leads, and a heat dissipation layer adhered to an other surface of the film, the heat dissipation layer including a graphite material layer, a protection layer formed on a surface of the graphite material layer to cover the graphite material layer, and an adhesion layer formed on an other surface of the graphite material layer to adhere the heat dissipation layer to the other surface of the film.

Abstract: Provided is a high-power device having a thermocouple (thermoelectric couple) for measuring the temperature of a transistor constituting a high-power device. The high-power device includes a heating element, a thermocouple formed adjacent to the heating element, and a dielectric body formed between the heating element and the thermocouple.

Abstract: An integrated circuit (IC) device includes a substrate having a top surface including substrate pads, and a through substrate via (TSV) die including a semiconductor substrate including a topside semiconductor surface having active circuitry and a bottomside surface. The topside semiconductor surface includes bonding connectors that are coupled to the substrate pads on the top surface of the substrate. A plurality of TSVs include an inner metal core that extends from the topside semiconductor surface to protruding TSV tips which extend out from the bottomside surface. At least one of the plurality of TSVs are dummy TSVs that have their protruding TSV tips exclusive of any electrically connection thereto that provide additional surface area that enhances heat dissipation from the bottomside of the TSV die.

Abstract: A power module includes a pair of power devices that are stacked with a plate-shaped output electrode arranged therebetween, and an N-electrode and a P-electrode that are stacked with the pair of power devices arranged therebetween. The output electrode is anisotropic such that the thermal conductivity in a direction orthogonal to the stacking direction is greater than the thermal conductivity in the stacking direction. Also, the output electrode extends in the orthogonal direction from a stacked area where the pair of power devices are stacked. The N-electrode and the P-electrode extend in the orthogonal direction while maintaining an opposing positional relationship.

Abstract: A semiconductor unit includes a semiconductor chip, a ceramic substrate having a circuit pattern on which the semiconductor chip is mounted, and a temperature sensor for detecting a temperature. The semiconductor unit further includes a pressing member for retaining the temperature sensor by pressing against the ceramic substrate.

Abstract: An integrated circuit (IC) package is disclosed. The IC package includes a first die; and a second die bonded to the CPU die in a three dimensional packaging layout.

Abstract: Provided is a multi-layered semiconductor apparatus with improved heat diffusion and improved heat release. The multi-layered semiconductor apparatus (100) includes a plurality of layered semiconductor chips (20-1, 20-2) that each include at least one circuit region, and the circuit regions are arranged such that heat generated by the circuit regions as a result of the circuit regions being driven is spread out. The multi-layered semiconductor apparatus (100) further comprises a heat releasing section (50) that releases the heat generated by the circuit regions, and the circuit regions are arranged such that there is less thermal resistance between the heat releasing section and circuit regions that generate a greater amount of heat per unit area.

Abstract: The present disclosure relates to a junction box and a manufacturing method thereof. The junction box includes terminal member to which electric energy is supplied, a diode provided to the terminal member, and a heat sink brought into close contact with the diode by molding. The junction box may prevent malfunction and failure while achieving size reduction thereof.

Abstract: A semiconductor device includes a substrate with conductive traces. A semiconductor die is mounted with an active surface oriented toward the substrate. An underfill material is deposited between the semiconductor die and substrate. A recess is formed in an interior portion of the semiconductor die that extends from a back surface of the semiconductor die opposite the active surface partially through the semiconductor die such that a peripheral portion of the back surface of the semiconductor die is offset with respect to a depth of the recess. A thermal interface material (TIM) is deposited over the semiconductor die and into the recess such that the TIM in the recess is laterally supported by the peripheral portion of the semiconductor die to reduce flow of the TIM away from the semiconductor die. A heat spreader including protrusions is mounted over the semiconductor die and contacts the TIM.

Abstract: A semiconductor device includes a substrate, a semiconductor element disposed on the substrate, and a heat conductive member composed of a solder material. The heat conductive member covers the semiconductor element, and is connected to a connection pad formed on the substrate. A heat radiator is disposed on the heat conductive member. The heat conductive member thermally connecting the semiconductor element to the heat radiator reduces the risk that electromagnetic noise may be emitted from or may be incident on the semiconductor element.

Abstract: A package-on-package structure includes first and second package structures and bumps. The first package structure includes a carrier, a chip configured on the carrier, a heat spreader, and an encapsulant. The chip is electrically connected to the carrier through conductive wires. The heat spreader includes a support portion located on the chip and connection portions located respectively at two opposite sides of the support portion. The heat spreader has a circuit layer thereon, covers the chip and the conductive wires, and electrically connects the carrier through the circuit layer on the connecting portions. The encapsulant encapsulates the chip, the conductive wires, a portion of the heat spreader, and a portion of the carrier. The bumps are configured on the support portion. The second package structure is configured on the first package structure and is electrically connected to the first package structure through the bumps.

Abstract: Thermally regulated semiconductor devices having reduced thermally induced defects are provided, including associated methods. Such a device can include a heat spreader having a monolayer of diamond particles within a thin metal matrix and a semiconductor material thermally coupled to the heat spreader. In one aspect, the coefficient of thermal expansion difference between the heat spreader and the semiconductor material is less than or equal to about 50%.

Abstract: This power converter includes a power-conversion semiconductor element, an electrode conductor having a substantially flat upper end surface, and a sealant. The sealant allows the substantially flat upper end surface of the electrode conductor to be exposed at an upper surface of the sealant, and provides electrical connection with an external device at the upper end surface of the exposed electrode conductor.

Abstract: According to one embodiment, a semiconductor apparatus includes a semiconductor device, a heat spreader, a regulating unit, a containing unit, and a holding unit. The heat spreader is bonded to the semiconductor device with an interposed solder layer. The regulating unit is configured to regulate a dimension between the semiconductor device and the heat spreader. The containing unit is configured to contain melted solder in an interior of the containing unit. The holding unit is configured to allow melted solder held in an interior of the holding unit. The holding unit is configured to replenish the melted solder in the case where an amount of the melted solder contained in the containing unit is insufficient. The holding unit is configured to recover the melted solder in the case where the amount of the melted solder contained in the containing unit is excessive.

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: Methods and apparatus relating to very large scale FET arrays for analyte measurements. ChemFET (e.g., ISFET) arrays may be fabricated using conventional CMOS processing techniques based on improved FET pixel and array designs that increase measurement sensitivity and accuracy, and at the same time facilitate significantly small pixel sizes and dense arrays. Improved array control techniques provide for rapid data acquisition from large and dense arrays. Such arrays may be employed to detect a presence and/or concentration changes of various analyte types in a wide variety of chemical and/or biological processes. In one example, chemFET arrays facilitate DNA sequencing techniques based on monitoring changes in hydrogen ion concentration (pH), changes in other analyte concentration, and/or binding events associated with chemical processes relating to DNA synthesis.

Abstract: A semiconductor device is formed by molding using a resin with a semiconductor element and one or two heat dissipating plates contained therein, said one or two heat dissipating plates being disposed to face one surface or both the surfaces of the semiconductor element. An intermediate layer is formed by spraying a metal powder to the semiconductor element and to one of or both of the heat dissipating plates using a cold spray method, and the semiconductor element and the heat dissipating plate are bonded together using a solder with the intermediate layer therebetween.

Abstract: Methods and apparatus relating to very large scale FET arrays for analyte measurements. ChemFET (e.g., ISFET) arrays may be fabricated using conventional CMOS processing techniques based on improved FET pixel and array designs that increase measurement sensitivity and accuracy, and at the same time facilitate significantly small pixel sizes and dense arrays. Improved array control techniques provide for rapid data acquisition from large and dense arrays. Such arrays may be employed to detect a presence and/or concentration changes of various analyte types in a wide variety of chemical and/or biological processes. In one example, chemFET arrays facilitate DNA sequencing techniques based on monitoring changes in hydrogen ion concentration (pH), changes in other analyte concentration, and/or binding events associated with chemical processes relating to DNA synthesis.

Abstract: A metal matrix composite is disclosed that includes graphene nanoplatelets dispersed in a metal matrix. The composite provides for improved thermal conductivity. The composite may be formed into heat spreaders or other thermal management devices to provide improved cooling to electronic and electrical equipment and semiconductor devices.

Abstract: A semiconductor device comprising power distribution wires wherein; a portion of said wires have thermal connection to the semiconductor layer and said thermal connection designed to conduct heat but to not conduct electricity.

Abstract: A semiconductor apparatus includes: a semiconductor device including a first electrode; a substrate including a second electrode and a recess; and a heat-dissipating adhesive material to set the semiconductor device in the recess so as to arrange the first electrode close to the second electrode, wherein the first electrode is coupled to the second electrode and the heat-dissipating adhesive material covers a bottom surface and at least part of a side surface of the semiconductor device.

Abstract: A package structure of photodiode and a forming method of the same are provided. The method includes providing a heat-dissipation plate; placing a circuit board on the heat-dissipation plate, the circuit board having an opening exposing a top surface of the heat-dissipation plate and a first contact pad located on a peripheral area of the opening; placing a carrier with a metal cladding surface into the opening, the carrier connecting the top surface of the heat-dissipation plate; placing a photodiode chip on the carrier wherein the bottom area of the photodiode chip is less than the metal cladding surface such that a portion of the metal cladding surface is exposed; and electrically connecting the exposed metal cladding surface to the first contact pad.

Abstract: Between a logic LSI (4) arranged on one side of a DRAM (1) and jointed to the DRAM and a radiating member (6) arranged on the other side of the DRAM (1) for irradiating the heats of the DRAM (1) and the logic LSI (4), there is disposed a heat bypass passage (5), which extends inbetween while bypassing the DRAM (1). Thus, it is possible to provide a semiconductor device, which can irradiate the heat generated from the logic LSI such as CPU or GPU thereby to reduce the temperature rise and the temperature distribution.

Abstract: A light emitting chip includes a substrate, an epitaxial structure comprising a first semiconductor layer, a light emitting layer and a second semiconductor layer, a current conducting structure formed on a bottom side of the first semiconductor layer of the epitaxial structure, and heat conducting protrusions formed on a top side of the substrate. Each of the heat conducting protrusions includes a carbon nanotube layer vertically grown thereon. The heat conducting protrusions are embedded into the current conducting structure to thermally connect with the first semiconductor layer. A method for manufacturing the light emitting chip is also disclosed.

Abstract: One or more heating elements are disposed on a semiconductor substrate proximate a temperature sensitive circuit disposed on the substrate (e.g., bandgap circuit, oscillator). The heater element(s) can be controlled to heat the substrate and elevate the temperature of the circuit to one or more temperature points. One or more temperature measurements can be made at each of the one or more temperature points for calibrating one or more reference values of the circuit (e.g., bandgap voltage).

Abstract: An integrated circuit, a method of operating the integrated circuit, and a method of fabricating the integrated circuit are disclosed. According to one of the broader forms of the invention, a method and apparatus involve an integrated circuit that includes a heat transfer structure having a chamber that has a fluid disposed therein and that extends between a heat generating portion and a heat absorbing portion. Heat is absorbed into the fluid from the heat generating portion, and the fluid changes from a first phase to a second phase different from the first phase when the heat is absorbed. Heat is released from the fluid to the heat absorbing portion, and the fluid changes from the second phase to the first phase when the heat is released.

Abstract: A semiconductor structure comprising a semiconductor unit, a first conductive structure, a first conductive plug, and a second conductive structure is provided. The semiconductor unit has a substrate on a first side of the semiconductor unit. The substrate has at least a hole. The first conductive plug is in the hole and the hole may be full of the conductive plug. The first conductive structure is on the surface of the semiconductor unit. The surface is at the first side of the semiconductor unit. The second conductive structure is on a surface at a second side of the substrate of the semiconductor unit.

Abstract: A semiconductor package system is provided including: a semiconductor chip; a substrate having a substrate opening and a vertical build-up wing, the substrate having the semiconductor chip mounted thereon with the vertical build-up wing circumscribed by vertical planes of a perimeter of, and spaced apart from, the semiconductor chip; a first heat slug attached above the substrate at a first horizontal plane and to a first surface of the semiconductor chip, the semiconductor chip at least partially encapsulated by the first heat slug; and a second heat slug attached to the substrate at a second horizontal plane above the first horizontal plane and to a second surface of the semiconductor chip through the substrate opening.

Abstract: A thermal interface material comprises an epoxy resin derived from nutshell oil or an epoxidized dimer fatty acid, or both, and fusible metal particles substantially devoid of added lead. Optionally, the TIM comprises a catalyst for the epoxy functionality.

Abstract: A semiconductor package includes a semiconductor die having contact pads. An encapsulant is disposed around the semiconductor die, and conductive vias are disposed in the encapsulant. Electrically conductive traces are disposed between the contact pads and conductive vias, a thermally conductive channel is disposed in the encapsulant separate from the conductive vias, and a thermally conductive layer is disposed over an area of heat generation of the semiconductor die. A thermally conductive trace is disposed between the thermally conductive layer and thermally conductive channel. The thermally conductive layer, thermally conductive trace, and thermally conductive channel are electrically isolated from the contact pads of the semiconductor die and the electrically conductive traces. The semiconductor package further comprises broad thermal traces disposed over the encapsulant, and a thermally conductive material interconnecting the broad thermal traces and the thermally conductive layer.

Abstract: Embodiments of the present invention relate to the use of stamping to form features on a lead frame of a semiconductor device package. In one embodiment, portions of the lead frame such as pins are moved out of the horizontal plane of a diepad by stamping. In certain embodiments, indentations or a complex cross-sectional profile, such as chamfered, may be imparted to portions of the pins and/or diepad by stamping. The complexity offered by such a stamped cross-sectional profile serves to enhance mechanical interlocking of the lead frame within the plastic molding of the package body. Other techniques such as selective electroplating and/or formation of a brown oxide guard band to limit spreading of adhesive material during die attach, may be employed alone or in combination to facilitate fabrication of a package having such stamped features.

Abstract: A semiconductor package is described. The semiconductor package includes a substrate and an integrated heat spreader disposed above and coupled with the substrate. A cavity is disposed between the substrate and the integrated heat spreader. A semiconductor die is disposed above the substrate and in the cavity. An array of first-level solder joints is disposed between the substrate and the semiconductor die. A layer of magnetic particle-based composite material is also disposed in the cavity.

Abstract: A semiconductor device has a first substrate with a central region. A plurality of bumps is formed around a periphery of the central region of the first substrate. A first semiconductor die is mounted to the central region of the first substrate. A second semiconductor die is mounted to the first semiconductor die over the central region of the first substrate. A height of the first and second die is less than or equal to a height of the bumps. A second substrate has a thermal conduction channel. A surface of the second semiconductor die opposite the first die is mounted to the thermal conductive channel of the second substrate. A thermal interface layer is formed over the surface of the second die. The bumps are electrically connected to contact pads on the second substrate. A conductive plane is formed over a surface of the second substrate.

Abstract: An integrated circuit package includes a package core and a primary circuitry chip mounted on the package core. The primary circuitry chip has an active surface in which the core circuitry is fabricated. The active surface of the primary circuitry chip faces the package core and includes contacts. The integrated circuit package further includes an auxiliary circuit chip assembled to the package core and having contacts facing and electrically connected to the contacts of the primary circuitry chip.