Abstract: A high-frequency transmission module includes a first chip, a second chip, and a conductive wire. The first chip includes a first top surface and a number of pads arranged along a periphery of the first top surface. The pads include a first bonding pad. The second chip includes a second top surface and a second bonding pad on the second top surface. The second chip is positioned on the first top surface such that the pads are uncovered by the second chip and the second bonding pad is mostly closed to the first bonding pad. The conductive wire bonds to the first bonding pad and the second bonding pad to electrically connect the second chip to the first chip and is configured to transmit high-frequency signals between the first chip and the second chip.

Abstract: A semiconductor device has a carrier with a die attach area. A semiconductor die is mounted to the die attach area with a back surface opposite the carrier. A modular interconnect unit is mounted over the carrier and around or in a peripheral region around the semiconductor die such that the modular interconnect unit is offset from the back surface of the semiconductor die. An encapsulant is deposited over the carrier, semiconductor die, and modular interconnect unit. A first portion of the encapsulant is removed to expose the semiconductor die and a second portion is removed to expose the modular interconnect unit. The carrier is removed. An interconnect structure is formed over the semiconductor die and modular interconnect unit. The modular interconnect unit includes a vertical interconnect structures or bumps through the semiconductor device. The modular interconnect unit forms part of an interlocking pattern around the semiconductor die.

Abstract: A number of first hard mask portions are formed on a dielectric layer to vertically shadow a respective one of a number of underlying gate structures. A number of second hard mask filaments are formed adjacent to each side surface of each first hard mask portion. A width of each second hard mask filament is set to define an active area contact-to-gate structure spacing. A first passage is etched between facing exposed side surfaces of a given pair of neighboring second hard mask filaments and through a depth of the semiconductor wafer to an active area. A second passage is etched through a given first hard mask portion and through a depth of the semiconductor wafer to a top surface of the underlying gate structure. An electrically conductive material is deposited within both the first and second passages to respectively form an active area contact and a gate contact.

Abstract: A semiconductor device has 3n, 3n+1, and 3n+2 connector lines that are formed together. The 3n+1 connector line is located between the 3n connector line and the 3n+2 connector line. The first fringe pattern pad is located at the terminus of the 3n connector line and is formed with a wider space than the width of the 3n connector line. The second fringe pattern pad is located at the terminus of the 3n+1 connector line and is formed with a wider width than the width of the 3n+1 connector line. The third fringe pattern pad is located at the terminus of the 3n+2 connector line and is formed with a wider width than the width of the 3n+2 connector line. The second fringe pattern pad is positioned closer to a memory array as compared with the terminus of each connector line with the first and third fringe pattern pads.

Abstract: Disclosed embodiments include wire joints and methods of forming wire joints that can enable realization of fine pitch joints and collapse control for various packages. A first embodiment is a structure comprising a first substrate, a second substrate, and a wire joint. The first substrate comprises a first bonding surface, and the second substrate comprises a second bonding surface. The first bonding surface is opposite and faces the second bonding surface. The wire joint is attached to and between the first bonding surface and the second bonding surface.

Abstract: A memory device has a laminated chip package and a controller plate. In the laminated chip package, a plurality of memory chips are laminated. An interposed chip is laminated between the laminated chip package and the controller plate. A plurality of opposing wiring electrodes are formed at an opposing surface of the controller plate. A plurality of outside wiring electrodes are formed on the rear side of the opposing surface. Connection electrodes connecting the opposing wiring electrodes and the outside wiring electrodes are formed on the side surface of the controller plate. The interposed chip has a plurality of interposed wiring electrodes. The plurality of interposed wiring electrodes are formed with a common arrangement pattern common with an arrangement pattern of the plurality of opposing wiring electrodes. The controller plate is laid on the interposed chip.

Abstract: A semiconductor package includes a substrate having opposite first and second surfaces and a ground layer therein. Further, the second surface has at least a recessed portion for exposing portions of the ground layer. The semiconductor package further includes a semiconductor chip disposed on the first surface of the substrate; an encapsulant formed on the first surface of the substrate for encapsulating the semiconductor chip; and a metal layer covering the encapsulant and the substrate and extending to the recessed portion for electrically connecting the ground layer. As such, the space for circuit layout is increased and the circuit layout flexibility is improved.

Abstract: Embodiments of the present disclosure flip-chip packaging techniques and configurations. An apparatus may include a package substrate having a plurality of pads formed on the package substrate, the plurality of pads being configured to receive a corresponding plurality of interconnect structures formed on a die and a fluxing underfill material disposed on the package substrate, the fluxing underfill material comprising a fluxing agent configured to facilitate formation of solder bonds between individual interconnect structures of the plurality of interconnect structures and individual pads of the plurality of pads and an epoxy material configured to harden during formation of the solder bonds to mechanically strengthen the solder bonds. Other embodiments may also be described and/or claimed.

Abstract: An article of manufacture includes a semiconductor die (110) having an integrated circuit (105) on a first side of the die (110), a diffusion barrier (125) on a second side of the die (110) opposite the first side, a mat of carbon nanotubes (112) rooted to the diffusion barrier (125), a die attach adhesive (115) forming an integral mass with the mat (112) of the carbon nanotubes, and a die pad (120) adhering to the die attach adhesive and (115) and the mat (112) of carbon nanotubes for at least some thermal transfer between the die (110) and the die pad (120) via the carbon nanotubes (112). Other articles, integrated circuit devices, structures, and processes of manufacture, and assembly processes are also disclosed.

Abstract: A semiconductor wafer includes semiconductor chips divided by a dicing line, one of the semiconductor chips including terminals of an identical potential; a wiring located on the dicing line, and electrically connecting the terminals to each other; and a pad electrically connected through the wiring to the terminals, wherein the pad is located entirely on the semiconductor chip and is not present on the dicing line.

Abstract: Etched trenches in a bond material for die singulation, and associated systems and methods are disclosed. A method for solid state transducer device singulation in accordance with one embodiment includes forming a plurality of trenches by etching through a metallic bond material forming a bond between a carrier substrate and a plurality of the dies and singulating the carrier substrate along the trenches to separate the dies. In particular embodiments, the trenches extend into the carrier substrate. In further particular embodiments, the dies are at least partially encapsulated in a dielectric material.

Abstract: This invention provides a package structure of three-dimensional stacking dice and its manufacturing method. This invention employs the Through-Silicon-Vias (TSVs) technology to establish vertical electrical connection of the three-dimensional stacking dice and a redistribution layer between a blind hole-on-pad and a vertical through hole formed by the TSVs technology to direct the electrical connection from a first surface to an opposite second surface of this structure. In addition, this invention employs a conductive bump completely covering the pads jointed together between the stacking dice to avoid breakage of the pads. The reliability of the three-dimensional stacking dice of the present invention is increased.

Abstract: A system and method are provided for fabricating a low electric resistance ohmic contact, or interface, between a Carbon Nanotube (CNT) and a desired node on a substrate. In one embodiment, the CNT is a Multiwalled, or Multiwall, Carbon Nanotube (MWCNT), and the interface provides a low electric resistance ohmic contact between all conduction shells, or at least a majority of conduction shells, of the MWCNT and the desired node on the substrate. In one embodiment, a Focused Electron Beam Chemical Vapor Deposition (FEB-CVD) process is used to deposit an interface material near an exposed end of the MWCNT in such a manner that surface diffusion of precursor molecules used in the FEB-CVD process induces lateral spread of the deposited interface material into the exposed end of the MWCNT, thereby providing a contact to all conduction shells, or at least a majority of the conduction shells, of the MWCNT.

Abstract: One aspect of the present invention is a method of making an electronic device. According to one embodiment, the method comprises depositing a cap layer containing at least one dopant onto a gapfill metal and annealing so that the at least one dopant migrates to grain boundaries and/or interfaces of the gapfill metal. Another aspect of the present invention is an electronic device.

Abstract: A test probe head for probing integrated circuit (IC) chips and method of making test heads. The test head includes an array of vias (e.g., annular vias or grouped rectangular vias) through, and exiting one surface of, a semiconductor layer, e.g., a silicon layer. The vias, individual test probe tips, may be on a pitch at or less than fifty microns (50 ?m). The probe tips may be stiffened with SiO2 (and optionally silicon) extending along the sidewalls. A redistribution layer connects individual test probe tips externally. The probe tips may be capped with a hardening cap that also caps stiffening SiO2 and silicon along the tip sidewall.

Abstract: A chip design (1) comprising an external supply connection (VBAT), an internal supply connection (VDD), an integrated circuit (2) that is coupled to the internal supply connection (VDD) for voltage supply, and a fuse (3) that electrically connects the internal supply connection (VBAT) and is arranged within the chip design (1).

Abstract: A semiconductor package having an embedded die and solid vertical interconnections, such as stud bump interconnections, for increased integration in the direction of the z-axis (i.e., in a direction normal to the circuit side of the die). The semiconductor package can include a die mounted in a face-up configuration (similar to a wire bond package) or in a face-down or flip chip configuration.

Abstract: An electrical interconnect providing an interconnect between contacts on an IC device and contact pads on a printed circuit board (PCB). The electrical interconnect includes a substrate with a plurality of through holes extending from a first surface to a second surface. A resilient material is located in the through holes. The resilient material includes an opening extending from the first surface to the second surface. A plurality of discrete, free-flowing conductive nano-particles are located in the openings of the resilient material. The conductive particles are substantially free of non-conductive materials. A plurality of first contact members are located in the through holes adjacent the first surface and a plurality of second contact members are located in the through holes adjacent the second surface. The first and second contact members are electrically coupled to the nano-particles.

Abstract: Provided are a printed circuit board (PCB) and a semiconductor package including the same. The PCB includes a core layer having a stacked structure including at least a first layer made of a first material that has a first coefficient of thermal expansion (CTE) and a second layer made of a second material that has a second CTE different from the first CTE, an upper wiring layer disposed on a first surface of the core layer, and a lower wiring layer disposed on a second surface of the core layer opposite the first surface.

Abstract: Integrated circuits and methods for fabricating integrated circuits are provided. In an embodiment, an integrated circuit includes an interlayer dielectric material having a top surface and overlying semiconductor devices formed on a semiconductor substrate. The integrated circuit includes a metal interconnect formed in the interlayer dielectric material. The metal interconnect includes an upper surface to which an insulating monolayer is bonded. The integrated circuit further includes a dielectric cap that overlies the top surface of the interlayer dielectric material and encapsulates the insulating monolayer.

Abstract: There are disclosed herein various implementations of semiconductor packages having a selectively conductive film interposer. In one such implementation, a semiconductor package includes a first active die having a first plurality of electrical connectors on a top surface of the first active die, a selectively conductive film interposer situated over the first active die, and a second active die having a second plurality of electrical connectors on a bottom surface of the second active die. The selectively conductive film interposer may be configured to serve as an interposer and to selectively couple at least one of the first plurality of electrical connectors to at least one of the second plurality of electrical connectors.

Abstract: A chip arrangement includes semiconductor chips coupled to opposing sides of an insulating layer. The arrangement includes a first semiconductor chip having a first chip surface presenting a first chip conductive region. An electrically insulating layer includes a first layer surface presenting a first layer conductive region, and a second, opposing surface presenting a second layer conductive region. The electrically insulating layer is coupled to the first semiconductor chip by applying the first layer conductive region to the first chip conductive region. The electrically insulating layer is then coupled to the second chip conductive region by applying the second layer conductive region to the second chip conductive region.

Abstract: A semiconductor package includes: a chip having an active surface with a plurality of electrode pads and an inactive surface opposite to the active surface; an encapsulant encapsulating the chip and having opposite first and second surfaces, the first surface being flush with the active surface of the chip; and first and second metal layers formed on the second surface of the encapsulant, thereby providing a rigid support to the overall structure to prevent warpage and facilitating heat dissipation of the overall structure.

Abstract: The present invention relates to an apparatus combining bypass diode and wire. According to the present invention, the bypass diode can connect with the wire directly. It is not necessary to reserve an extra region on the substrate of the solar cell as the wire soldering area. Thereby, the required area of the ceramic substrate is reduced, and hence lowering the manufacturing cost of the solar cell substantially.

Abstract: Embodiments of stacked die assemblies for an IC are disclosed. One embodiment includes a first interposer; a second interposer; a first integrated circuit die, a second integrated circuit die, and a plurality of components. The first integrated circuit die is interconnected to the first interposer and the second interposer, and the second integrated circuit die is interconnected to the second interposer. The plurality of components interconnect the first integrated circuit die to the first interposer and the second interposer. The plurality of components that interconnect the first integrated circuit die to the first interposer and the second interposer are located outside an interconnect restricted area of the first interposer and the second interposer, and signals are routed between the first interposer and the second interposer via the first integrated circuit die and the plurality of components, avoiding the interconnect restricted area of the first interposer and the second interposer.

Abstract: A semiconductor packaging method includes providing a substrate having a plurality of connection pads; mounting a chip on the substrate, wherein the chip comprises a plurality of copper-containing bumps directly coupled to the connection pads, and each of the copper-containing bumps comprises a ring surface; forming an anti-dissociation gel between the substrate and the chip, wherein the anti-dissociation gel comprises a plurality of anti-dissociation substances, and the ring surfaces of the copper-containing bumps are covered by the anti-dissociation substances.

Abstract: Transparent electrodes are manufactured. In accordance with various example embodiments, a transparent electrode is manufactured by generating a solution including a composite material having nanotubes and a conjugated polymer, in which the nanotubes constitute a majority of the composite material by weight. The conjugated polymer is used to disperse the nanotubes in the solution, and the solution is coated onto a substrate to form an electrode including a network of the carbon nanotubes.

Abstract: Provided is a technique capable of improving the reliability of a semiconductor device having a slit made over a main surface of a semiconductor substrate, so as to surround each element formation region. In the technique, a second passivation film covers the side surface of an opening made to make the upper surface of a sixth-layer interconnection M6 used for bonding pads naked, and the inner walls (the side surfaces and the bottom surface) of a slit made to surround the circumference of a guard ring and made in a first passivation film, an insulating film for bonding, and an interlayer dielectric, so as to cause the bottom thereof not to penetrate through a barrier insulating film.

Abstract: The present invention relates to a film for flip chip type semiconductor back surface, which is to be disposed on the back surface of a semiconductor element to be flip chip-connected onto an adherend, the film containing a resin and a thermoconductive filler, in which the content of the thermoconductive filler is at least 50% by volume of the film, and the thermoconductive filler has an average particle size relative to the thickness of the film of at most 30% and has a maximum particle size relative to the thickness of the film of at most 80%.

Abstract: A semiconductor device including a dielectric layer formed on the surface of a post-passivation interconnect (PPI) structures. A polymer layer is formed on the dielectric layer and patterned with an opening to expose a portion of the dielectric layer. The exposed portion of the dielectric layer is then removed to expose a portion of the PPI structure. A solder bump is then formed over and electrically connected to the first portion of the PPI structure.

Abstract: A stress reduction apparatus comprises a metal structure formed over a substrate, an inter metal dielectric layer formed over the substrate, wherein a lower portion of the metal structure is embedded in the inter metal dielectric layer and an inverted cup shaped stress reduction layer formed over the metal structure, wherein an upper portion of the metal structure is embedded in the inverted cup shaped stress reduction layer.

Abstract: The semiconductor device of the invention includes a transistor, an insulating layer provided over the transistor, a first conductive layer (corresponding to a source wire or a drain wire) electrically connected to a source region or a drain region of the transistor through an opening portion provided in the insulating layer, a first resin layer provided over the insulating layer and the first conductive layer, a layer containing conductive particles which is electrically connected to the first conductive layer through an opening portion provided in the first resin layer, and a substrate provided with a second resin layer and a second conductive layer serving as an antenna. In the semiconductor device having the above-described structure, the second conductive layer is electrically connected to the first conductive layer with the layer containing conductive particles interposed therebetween. In addition, the second resin layer is provided over the first resin layer.

Abstract: A semiconductor device which includes a substrate, a semiconductor chip which is mounted on the substrate, a package in which an upper surface of the substrate and the semiconductor chip are sealed using an insulating material, and a molding material which is exposed to the upper surface of the package. In addition, the device includes a lead of which one end is connected to the mold material and the other end is electrically connected to the substrate, which is integrally formed of the same material as from a connection portion with the mold material to a connection portion with the substrate, and of which the connection portion with the mold material is exposed to the upper surface of the package.

Abstract: An integrated circuit structure can include a first interposer and a second interposer. The first interposer and the second interposer can be coplanar. The integrated circuit structure further can include at least a first die that is coupled to the first interposer and the second interposer.

Abstract: Techniques for fabricating self-aligned contacts in III-V FET devices are provided. In one aspect, a method for fabricating a self-aligned contact to III-V materials includes the following steps. At least one metal is deposited on a surface of the III-V material. The at least one metal is reacted with an upper portion of the III-V material to form a metal-III-V alloy layer which is the self-aligned contact. An etch is used to remove any unreacted portions of the at least one metal. At least one impurity is implanted into the metal-III-V alloy layer. The at least one impurity implanted into the metal-III-V alloy layer is diffused to an interface between the metal-III-V alloy layer and the III-V material thereunder to reduce a contact resistance of the self-aligned contact.

Abstract: A method of forming a semiconductor package may include providing a first package including a first semiconductor chip mounted on a first package substrate having a via-hole and molded by a first mold layer, providing a second package including a second semiconductor chip mounted on a second package substrate having a connection pad and molded by a second mold layer, stacking the first package on the second package to vertically align the via-hole with the connection pad, forming a through-hole penetrating the first and second packages and exposing the connection pad, and forming an electrical connection part in the through-hole. The electrical connection part may electrically connect the first package and the second package to each other.

Abstract: A power semiconductor device has the power semiconductor elements having back surfaces bonded to wiring patterns and surface electrodes, cylindrical communication parts having bottom surfaces bonded on the surface electrodes of the power semiconductor elements and/or on the wiring patterns, a transfer mold resin having concave parts which expose the upper surfaces of the communication parts and cover the insulating layer, the wiring patterns, and the power semiconductor elements. External terminals have one ends inserted in the upper surfaces of the communication parts and the other ends guided upward, and at least one external terminal has, between both end parts, a bent area which is bent in an L shape and is embedded in the concave part of the transfer mold resin.

Abstract: A semiconductor package includes a carrier strip having a die cavity and bump cavities. A semiconductor die is mounted in the die cavity of the carrier strip. In one embodiment, the semiconductor die is mounted using a die attach adhesive. In one embodiment, a top surface of the first semiconductor die is approximately coplanar with a top surface of the carrier strip proximate to the die cavity. A metal layer is disposed over the carrier strip to form a package bump and a plated interconnect between the package bump and a contact pad of the first semiconductor die. An underfill material is disposed in the die cavity between the first semiconductor die and a surface of the die cavity. A passivation layer is disposed over the first semiconductor die and exposes a contact pad of the first semiconductor die. An encapsulant is disposed over the carrier strip.

Abstract: A semiconductor device package including a substrate, first and second solder joints, a die pad, leads and enhancement elements surrounding the die pad, a chip electrically connected to the leads, and a package body encapsulating the chip, portions of the leads, and portions of the enhancement elements, but leaving exposed at least a side surface of each enhancement element. Side surfaces of the enhancement elements and the package body are coplanar. The substrate includes first pads corresponding to the leads and second pads corresponding to the enhancement elements. The first solder joints are disposed between the first pads and the leads. The second solder joints are disposed between the second pads and the enhancement elements. The second solder joints contact side surfaces of the enhancement elements. The surface area of the second pads is greater than the surface area of the corresponding enhancement elements.

Abstract: A protection structure of a pad is provided. The pad is disposed in a dielectric layer on a semiconductor substrate and the pad includes a connection region and a peripheral region which encompasses the connection region. The protection structure includes at least a barrier, an insulation layer and a mask layer. The barrier is disposed in the dielectric layer in the peripheral region. The insulation layer is disposed on the dielectric layer. The mask layer is disposed on the dielectric layer and covers the insulation layer and the mask layer includes an opening to expose the connection region of the pad.

Abstract: Systems, apparatuses, and methods related to the design, fabrication, and manufacture of gallium arsenide (GaAs) integrated circuits are disclosed. Copper can be used as the contact material for a GaAs integrated circuit. Metallization of the wafer and through-wafer vias can be achieved through copper plating processes disclosed herein. To improve the copper plating, a seed layer formed in the through-wafer vias can be modified to increase water affinity, rinsed to remove contaminants, and activated to facilitate copper deposition. GaAs integrated circuits can be singulated, packaged, and incorporated into various electronic devices.

Abstract: Methods of manufacturing a semiconductor device are provided. The method includes forming an isolation region in a substrate to define active regions extending in a single direction and being spaced apart from each other by the isolation region, forming a conductive layer in the isolation region and the active regions, etching the conductive layer to form bit line trenches extending in a first direction that is non-perpendicular to the single direction, forming bit line patterns in respective ones of the bit line trenches, etching the conductive layer to form a plurality of plug trenches two dimensionally arrayed along the first direction and a second direction perpendicular to the first direction, and filling the plug trenches with an insulation material to define conductive plug patterns in portions of the active regions. Related semiconductor devices are also provided.

Abstract: Systems, apparatuses, and methods related to the design, fabrication, and manufacture of gallium arsenide (GaAs) integrated circuits are disclosed. Copper can be used as the contact material for a GaAs integrated circuit. Metallization of the wafer and through-wafer vias can be achieved through copper plating processes disclosed herein. To avoid warpage, the tensile stress of a conductive layer deposited onto a GaAs substrate can be offset by depositing a compensating layer having negative stress over the GaAs substrate. GaAs integrated circuits can be singulated, packaged, and incorporated into various electronic devices.

Abstract: A new method is provided for the creation of a solder bump. Conventional methods are initially followed, creating a patterned layer of Under Bump Metal over the surface of a contact pad. A layer of photoresist is next deposited, this layer of photoresist is patterned and developed creating a resist mask having a T-shape opening aligned with the contact pad. This T-shaped opening is filled with a solder compound, creating a T-shaped layer of solder compound on the surface of the layer of UBM. The layer of photoresist is removed, exposing the created T-shaped layer of solder compound, further exposing the layer of UBM. The layer of UBM is etched using the T-shaped layer of solder compound as a mask. Reflow of the solder compound results in creating a solder ball.

Abstract: In a semiconductor module, a first heat sink is disposed on a rear surface of a first semiconductor chip constituting an upper arm, and a second heat sink is disposed on a front surface of the first semiconductor chip through a first terminal. A third heat sink is disposed on a rear surface of a second semiconductor chip constituting a lower arm, and a fourth heat sink is disposed on a front surface of the second semiconductor chip through a second terminal. A connecting part for connecting between the upper arm and the lower arm is integral with the first terminal, and is connected to the third heat sink while being inclined relative to the first terminal.

Abstract: The present invention provides a thick-film paste for printing the front-side of a solar cell device having one or more insulating layers. The thick-film paste comprises an electrically conductive metal, and a lead-tellurium-oxide dispersed in an organic medium.

Abstract: A method for forming a device is disclosed. A substrate with a contact region is provided. Vacancy defects are formed in the substrate. The vacancy defects have a peak concentration at a depth DV. A metal based contact is formed in the contact region. The metal based contact has a depth DC which is equal to about DV. The vacancy defects lower the resistance of the metal based contact with the substrate.

Abstract: A semiconductor die includes a crack stopper on an under-bump metallization (UBM) layer. The crack stopper is in the shape of hollow cylinder with at least two openings.

Abstract: A package includes a die having a conductive pad at a top surface of the die, a stud bump over and connected to the conductive pad, and a redistribution line over and connected to the stud bump. An electrical connector is over and electrically coupled to the redistribution line.

Abstract: A semiconductor package includes a substrate having first and second surfaces which face each other, a semiconductor chip mounted on the first surface, a first encapsulant formed on the first surface and at least partially encapsulating the semiconductor chip. A second encapsulant is formed on the second surface and first external connection terminals formed on the second surface to penetrate the second encapsulant. The external connection terminals have first ends in contact with the second surface. Second external connection terminals are attached to second ends of the first external connection terminals.