Abstract: A manufacturing method of a bump structure is provided. A substrate having at least one pad and a passivation layer is provided. The passivation layer has at least one first opening exposing the pad. An insulating layer is formed on the passivation layer. The insulating layer has at least one second opening located above the first opening. A metal layer is formed on the insulating layer. The metal layer electrically connects the pad through the first and second openings. A first bump is formed in the first and second openings. A second bump is formed on the first bump and a portion of the metal layer. The metal layer not covered by the second bump is partially removed by using the second bump as a mask, so as to form at least one UBM layer. The first bump is completely covered by the UBM layer and the second bump.

Abstract: A multi-chip integrated circuit (IC) package is provided which is configured to protect against failure due to warpage. The IC package may comprise a substrate, a level-one IC die and a plurality of level-two IC dies. The level-one IC die having a surface that is electrically coupled to the substrate. The plurality of level-two IC dies is stacked above the level-one IC die. The plurality of level-two IC dies may each have an active surface that is electrically coupled to the substrate. The plurality of level-two IC dies may be arranged side by side such that the active surfaces of the plurality of level-two IC dies are positioned substantially in a same plane. Relative to a single die configuration, the level-two IC dies are separated thereby inhibiting cracking, peeling and/or other potential failures due to warpage of the IC package.

Abstract: A semiconductor device includes: a plurality of semiconductor chips stacked on each other, each of the plurality of semiconductor chips having a semiconductor substrate and a wiring layer; a through electrode penetrating the semiconductor substrate in a thickness direction and electrically connected to each other between the semiconductor chips adjacent to each other; a conductor penetrating the semiconductor substrate in the thickness direction and not electrically connected between the other semiconductor chips; and an insulating separator penetrating the semiconductor substrate in the thickness direction and formed in a shape of a ring surrounding the conductor.

Abstract: Embodiments of the present disclosure describe a packaged semiconductor device that reduces stress on a semiconductor device caused by thermal expansion of the insulating material used in the packaged semiconductor device. In one embodiment, an inactive semiconductor device is coupled to the top of active semiconductor device. Both the inactive and active devices are encapsulated by the insulating material. The configuration of the inactive device is selected based on its ability to absorb the expansion of the insulating material at operating temperature.

Abstract: A structure comprises a first semiconductor substrate, a first bonding layer deposited on a bonding side the first semiconductor substrate, a second semiconductor substrate stacked on top of the first semiconductor substrate and a second bonding layer deposited on a bonding side of the second semiconductor substrate, wherein the first bonding layer is of a horizontal length greater than a horizontal length of the second semiconductor substrate, and wherein there is a gap between an edge of the second bonding layer and a corresponding edge of the second semiconductor substrate.

Abstract: A stack package includes a first package having a first semiconductor chip and a first encapsulation member which seals the first semiconductor chip. A second package is stacked on the first package, and includes a second semiconductor chip and a second encapsulation member which seals the second semiconductor chip. Flexible conductors are disposed within the first encapsulation member of the first package in such a way as to electrically connect the first package and the second package.

Abstract: A solder includes Sn (tin), Bi (bismuth) and Zn (zinc), wherein the solder has a Zn content of 0.01% by weight to 0.1% by weight.

Abstract: In some embodiments, the semiconductor package includes a substrate having multiple layers, from a first layer to a final layer, a die coupled to the first layer, an electrical connector such as a solder ball coupled to the final layer, and a spiral trace disposed and electrically coupled between the die and the electrical connector. Inductance of the spiral trace is selected such that the package has a predetermined impedance. Material, cross-sectional area, number and density of windings, and total overall length of the spiral trace are selected accordingly. In other embodiments, the semiconductor package includes a substrate with multiple layers; a die coupled to the first of the layers; an electrical connector coupled to the final layer; and a spiral trace, in or on the substrate. The spiral trace is near the die, and electrically coupled between the die and the electrical connector.

Abstract: A ball grid array (BGA) includes a plurality of metal balls adapted for connection between an electrical circuit and a substrate. A first portion of the BGA contains a first group of the metal balls arranged according to a first pitch. A second portion of the BGA contains a second group of metal the balls arranged according to a second pitch that is less than the first pitch, to provide increased metal contact area and correspondingly enhanced thermal transfer capability.

Abstract: A semiconductor device includes: a wiring board which includes a first face and a second face and in which a conductor pattern and a through part are provided; an electronic component which includes an electrode pad forming face where an electrode pad is formed and which is housed in the through part so that the electrode pad forming face is provided on the first face side; a seal resin which is provided in the through part and the electrode pad forming face, seals the electronic component and includes a first plane exposing a connection face of the electrode pad; and a wiring pattern which is provided in the first face of the wiring board and the first plane of the seal resin and electrically connects the connection face of the electrode pad with a first connected face of the conductor pattern, and which includes a pad part.

Abstract: This disclosure relates generally to a semiconductor device and method of making the semiconductor device by pressing an electrical contact of a chip into a bonding layer on a carrier. The bonding layer is cured and coupled, at least in part, to the electrical contact. A molding layer is applied in contact with the chip and a first major surface of the bonding layer. Distribution circuitry is coupled to the electrical contact.

Abstract: A manufacturing method for a mounting structure of a semiconductor package component, including: applying a first adhesive with viscosity ?1 and a thixotropy index T1 at a position on the substrate, which is on an outer side of the mounted semiconductor package component; applying, on the first adhesive, a second adhesive with viscosity ?2 and a thixotropy index T2 so that the second adhesive gets in contact with an outer periphery part of the semiconductor package component; and forming, through a subsequent reflow process, a first adhesive part of the hardened first adhesive and a second adhesive part of the hardened second adhesive, wherein the first and second adhesives satisfy 30??2??1?300 (Pa·s) and 3?T2?T1?7, and sectional area S1 of the first adhesive part and sectional area S2 of the second adhesive part with respect to a direction perpendicular to a mounting surface of the substrate satisfy a relation S1?S2.

Abstract: Aspects of the present invention relate to a controlled collapse chip connection (C4) structures. Various embodiments include a method of forming a controlled collapse chip connection (C4) structure. The method can include: providing a precursor structure including: a substrate, a dielectric over the substrate, the dielectric including a plurality of trenches exposing a portion of the substrate, and a metal layer over the dielectric and the portion of the substrate in each of the plurality of trenches, forming a resist layer over the metal layer, forming a rigid liner over a surface of the resist layer and the metal layer, and forming solder over the rigid liner between portions of the resist layer.

Abstract: A solder bump structure for a ball grid array (BGA) includes at least one under bump metal (UBM) layer and a solder bump formed over the at least one UBM layer. The solder bump has a bump width and a bump height and the ratio of the bump height over the bump width is less than 1.

Abstract: A semiconductor device of the present invention includes a semiconductor chip; an internal pad for electrical connection formed on a surface of the semiconductor chip; a stress relaxation layer formed on the semiconductor chip and having an opening for exposing the internal pad; an under-bump layer formed so as to cover a face exposed in the opening on the internal pad, an inner face of the opening and a circumference of the opening on the stress relaxation layer; a solder terminal for electrical connection with outside formed on the under-bump layer; and a protective layer formed on the stress relaxation layer, encompassing a periphery of the under-bump layer and covering a side face of the under-bump layer.

Abstract: A semiconductor device which includes a first semiconductor chip 10, a first electrode 12 formed on the first semiconductor chip 10, a second semiconductor chip 20 to which the first semiconductor chip 10 is mounted, a second electrode 22 with a protrusion 24, which is formed on the second semiconductor chip 20, and a solder bump 14 which bonds the first electrode 12 and the second electrode 22 to cover at least a part of a side surface of the protrusion 24, and a method for manufacturing thereof are provided.

Abstract: A system of micro balls is disclosed for coupling an electronic component to a printed circuit board. The micro balls have a small diameter, and each contact pad may include an array of two or more micro balls. An example of a micro ball may include a polymer core, surrounded by a copper layer, which is in turn surrounded by a layer of solder.

Abstract: An integrated circuit (IC) chip is disclosed including a plurality of metal vertical interconnect accesses (vias) in a back end of line (BEOL) layer, a redistribution layer (RDL) on the BEOL layer, the BEOL layer having a plurality of bond pads, each bond pad connected to at least one corresponding metal via through the RDL; and a solder bump connected to each bond pad, wherein each solder bump is laterally offset from the corresponding metal via connected to the bond pad towards a center of the IC chip by an offset distance, wherein the offset distance is non-uniform across the IC chip. In one embodiment, the offset distance for each solder bump is proportionate to a distance between the center of the IC chip and the center of the corresponding solder bump pad structure for that solder bump.

Abstract: There is disclosed an integrated circuit (IC) package or semiconductor package including integrated spark or arc gaps which are uniquely configured to reduce the susceptibility of the package to being damaged from an electrostatic discharge (ESD) event. In an exemplary embodiment, each arc gap is collectively defined by an arc gap extension integrally connected to and protruding from the die pad of the package, and a corresponding lead thereof.

Abstract: A device includes a semiconductor material having a first surface. A first material is applied to the first surface and a fiber material is embedded in the first material.

Abstract: A substrate structure is provided, including a substrate and a strengthening member bonded to a surface of the substrate. The strengthening member has a CTE (Coefficient of Thermal Expansion) less than that of the substrate so as to effectively prevent warpage from occurring to the substrate structure.

Abstract: Methods of forming a microelectronic packaging structure and associated structures formed thereby are described. Those methods may include attaching a die to a carrier material, wherein the carrier material comprises a top layer and a bottom layer separated by an etch stop layer; forming a dielectric material adjacent the die, forming a coreless substrate by building up layers on the dielectric material, and then removing the top layer carrier material and etch stop layer from the bottom layer carrier material.

Abstract: A substrate structure is provided, including a substrate body and a plurality of circuits formed on the substrate body. At least one of the circuits has an electrical contact for connecting to an external element and the electrical contact is narrower in width than the circuit, thereby meeting the requirements of fine line/fine pitch and miniaturization, improving the product yield and reducing the fabrication cost.

Abstract: A method for manufacturing a chip package is provided. The method includes forming a layer over a carrier; forming further carrier material over the layer; selectively removing one or more portions of the further carrier material thereby releasing one or more portions of the layer from the further carrier material; and adhering a chip including one or more contact pads to the carrier via the layer.

Abstract: A method includes aligning a first electrical connector of a first package component to a second electrical connector of a second package component. With the first electrical connector aligned to the second electrical connector, a metal layer is plated on the first and the second electrical connectors. The metal layer bonds the first electrical connector to the second electrical connector.

Abstract: A semiconductor package structure includes a first substrate, a second substrate and an encapsulant. The first substrate comprises a plurality of first bumps and a plurality of first solder layers. Each of the first solder layers is formed on each of the first bumps and comprises a cone-shaped slot having an inner surface. The second substrate comprises a plurality of second bumps and a plurality of second solder layers. Each of the second solder layers is formed on each of the second bumps and comprises an outer surface. Each of the second solder layers is a cone-shaped body. The second solder layer couples to the first solder layer and is accommodated within the first solder layer. The inner surface of the cone-shaped slot contacts with the outer surface of the second solder layer. The encapsulant is formed between the first substrate and the second substrate.

Abstract: A device such as a wafer-level package (WLP) device is proposed in which a dielectric layer is disposed between a surface of a semiconductor device and a surface of a redistribution layer (RDL). The dielectric layer may have at least one interconnect extending through the dielectric layer. The dielectric layer may have a coefficient of thermal expansion (CTE) value in a direction perpendicular to the surface of the semiconductor device that is less than a threshold value, and a Young's modulus that is greater than another threshold value.

Abstract: A semiconductor device has a substrate having a plurality of conductive pads formed thereon. A semiconductor die is provided having a plurality of conductive pillars formed thereon. A solder is used for electrically coupling the conductive pillars to the conductive pads. Solder mask is formed on portions of the conductive pads to prevent the solder from flowing in an unwanted direction on the conductive pads.

Abstract: The present invention aims at providing a semiconductor device capable of reliably preventing a wire bonded to an island from being disconnected due to a thermal shock, a temperature cycle and the like in mounting and capable of preventing remarkable increase in the process time. In the semiconductor device according to the present invention, a semiconductor chip is die-bonded to the surface of an island, one end of a first wire is wire-bonded to an electrode formed on the surface of the semiconductor chip to form a first bonding section and the other end of the first wire is wire-bonded to the island to form a second bonding section, while the semiconductor device is resin-sealed. A double bonding section formed by wire-bonding a second wire is provided on the second bonding section of the first wire wire-bonded onto the island.

Abstract: A chip package is described which includes a first chip having a first surface and first sides having a first side-wall angle, and a second chip having a second surface and second sides having a second side-wall angle, which faces and is mechanically coupled to the first chip. The chip package is fabricated using a batch process, and the chips in the chip package were singulated from their respective wafers after the chip package is assembled. This is accomplished by etching the first and second side-wall angles and thinning the wafer thicknesses prior to assembling the chip package. For example, the first and/or the second side walls can be fabricated using wet etching or dry etching. Therefore, the first and/or the second side-wall angles may be other than vertical or approximately vertical.

Abstract: According to one exemplary implementation, a method includes lithographically forming a plurality of reticle images on a semiconductor wafer. The method further includes singulating the semiconductor wafer into an interposer die such that the interposer die includes at least a portion of a first reticle image and at least a portion of a second reticle image from the plurality of reticle images. The first reticle image and the second reticle image can be produced from a single reticle. The method can further include electrically connecting a first active die to a second active die through the interposer die. The method can also include electrically connecting the first active die to a package substrate through the interposer die.

Abstract: A semiconductor device and its manufacturing method are offered to increase the number of semiconductor devices obtained from a semiconductor wafer while simplifying a manufacturing process. After forming a plurality of pad electrodes in a predetermined region on a top surface of a semiconductor substrate, a supporter is bonded to the top surface of the semiconductor substrate through an adhesive layer. Next, an opening is formed in the semiconductor substrate in a region overlapping the predetermined region. A wiring layer electrically connected with each of the pad electrodes is formed in the opening. After that, a stacked layer structure including the semiconductor substrate and the supporter is cut by dicing along a dicing line that is outside the opening.

Abstract: A semiconductor element mounting board includes: a board having surfaces; a semiconductor element provided at a side of one of the surfaces of the board; a bonding agent layer through which the board and the semiconductor element are bonded together, the bonding agent layer having a storage modulus at 25° C. of 5 to 1,000 MPa; a first layer into which the semiconductor element is embedded, the first layer provided on the one surface of the board; a second layer provided on the other surface of the board, the second layer being constituted from the same material as that of the first layer, the constituent material of the second layer having the same composition ratio as that of the constituent material of the first layer; and surface layers provided on the first and second layers, respectively, each of the surface layers being formed from at least a single layer.

Abstract: A high melting point soldering layer includes a low melting point metal layer, a first high melting point metal layer disposed on a surface of the low melting point metal layer, and a second high melting point metal layer disposed at a back side of the low melting point metal layer. The low melting point metal layer, the first high melting point metal layer, and the second high melting point metal layer are mutually alloyed by transient liquid phase bonding, by annealing not less than a melting temperature of the low melting point metal layer, diffusing the metal of the low melting point metal layer into an alloy of the first high melting point metal layer and the second high melting point metal layer. The high melting point soldering layer has a higher melting point temperature than that of the low melting point metal layer.

Abstract: A method and structure for good adhesion of Intermetallic Compounds (IMC) on Cu pillar bumps are provided. The method includes depositing Cu to form a Cu pillar layer, depositing a diffusion barrier layer on top of the Cu pillar layer, and depositing a Cu cap layer on top of the diffusion barrier layer, where an intermetallic compound (IMC) is formed among the diffusion barrier layer, the Cu cap layer, and a solder layer placed on top of the Cu cap layer. The IMC has good adhesion on the Cu pillar structure, the thickness of the IMC is controllable by the thickness of the Cu cap layer, and the diffusion barrier layer limits diffusion of Cu from the Cu pillar layer to the solder layer. The method can further include depositing a thin layer for wettability on top of the diffusion barrier layer prior to depositing the Cu cap layer.

Abstract: One of the wafers in a semiconductor wafer to wafer stack can be rotated a predefined number of positions, relative to a previous wafer in the stack, and bonded in the position in which the maximum number of good die are aligned. An adjustment circuit on each die reroutes signals received from a pad that has been relocated due to rotation. A communication channel formed from a pair of pads that are interconnected by a Through Substrate Vias can be placed in each die and can convey selected information from one die to the next. A code representative of the position orientation of each die can be recorded in a Programmable Read Only Memory located on each die, or may be down loaded from a remote source. Any additional wafer may be stacked serially, and each one may be rotated relative to the wafer that precedes it in the stack.

Abstract: An embodiment of the disclosure includes a conductive feature on a semiconductor die. A substrate is provided. A bond pad is formed over the substrate. The bond pad has a first width. A polyimide layer is formed over the substrate and the bond pad. The polyimide layer has a first opening over the bond pad with a second width. A silicon-based protection layer overlies the polyimide layer. The silicon-based protection layer has a second opening over the bond pad with a third width. The first opening and the second opening form a combined opening having sidewalls to expose a portion of the bond pad. A UBM layer is formed over the sidewalls of combined opening to contact the exposed portion of the bond pad. A conductive feature overlies the UBM layer.

Abstract: A combined diode, lead assembly incorporating two expansion joints. The combined diode, lead assembly incorporating two expansion joints includes a diode having a first diode terminal and a second diode terminal, a first conductor and a second conductor. The first conductor includes a first terminal that is electrically coupled to the diode at the first diode terminal and a second terminal that is configured as a first expansion joint, which is configured to electrically couple to a first interconnecting-conductor and is configured to reduce a stress applied to the diode by the first conductor. The second conductor includes a first terminal that is electrically coupled to the diode at the second diode terminal and a second terminal that is configured as a second expansion joint, which is configured to electrically couple to a second interconnecting-conductor and is configured to reduce a stress applied to the diode by the second conductor.

Abstract: A chip package includes a stack of semiconductor dies or chips that are offset from each other, thereby defining a terrace with exposed pads. Moreover, surfaces of each of the semiconductor dies in the stepped terrace include two rows of first pads approximately parallel to edges of the semiconductor dies. Furthermore, the chip package includes a high-bandwidth ramp component, which is positioned approximately parallel to the terrace, and which has a surface that includes second pads arranged in at least two rows of second pads for each of the semiconductor dies. The second pads are electrically and mechanically coupled to the exposed first pads by connectors. Consequently, the electrical contacts in the chip package may have a conductive, a capacitive or, in general, a complex impedance. Furthermore, the chips and/or the ramp component may be positioned relative to each other using a ball-and-pit alignment technique.

Abstract: This disclosure relates to a bump structure on a substrate including a copper layer, wherein the copper layer fills an opening created in a dielectric layer and a polymer layer. The bump structure further includes an under-bump-metallurgy (UBM) layer lines the opening and the copper layer is deposited over the UBM layer. The bump structure further includes a surface of the copper layer facing away from the substrate is curved. This disclosure also relates to two bump structures with different heights on a substrate where a thickness of the first bump structure is different than a thickness of the second bump structure. This disclosure also relates to a semiconductor device including a bump structure.

Abstract: An integrated circuit structure includes a bond pad; an Mtop pad located directly underlying the bond pad; an Mtop-1 pad having at least a portion directly underlying the Mtop pad, wherein at least one of the Mtop pad and the Mtop-1 pad has a horizontal dimension smaller than a horizontal dimension of the bond pad; a plurality of vias interconnecting the Mtop pad and the Mtop-1 pad; and a bond ball on the bond pad. Each of the Mtop pad and the Mtop-1 pad has positive enclosures to the bond ball in all horizontal directions.

Abstract: A structure and method for monitoring interlevel dielectric stress damage. The structure includes a monitor solder bump and normal solder bumps; a set of stacked interlevel dielectric layers between the substrate and the monitor solder bump and the normal solder bumps, one or more ultra-low K dielectric layers comprising an ultra-low K material having a dielectric constant of 2.4 or less; a monitor structure in a region directly under the monitor solder bump in the ultra-low K dielectric layers and wherein the conductor density in at least one ultra-low K dielectric layer in the region directly under the monitor solder bumps is less than a specified minimum density and the conductor density in corresponding regions of the ultra-low K dielectric layers directly under normal solder bumps is greater than the specified minimum density.

Abstract: A semiconductor package structure comprises a substrate, a die bonded to the substrate, and one or more stud bump structures connecting the die to the substrate, wherein each of the stud bump structures having a stud bump and a solder ball encapsulating the stud bump to enhance thermal dissipation and reduce high stress concentrations in the semiconductor package structure.

Abstract: A method and system is provided by which multiple semiconductor die stacks can be assembled in a batch manner, and which also provides for die alignment tolerances required by microelectromechanical systems and other system-in-package applications. The batch process and accuracy is provided, in part, by an intermediate die attach carrier that has multiple die pockets fabricated to hold a set of die with an alignment required for the application. Die are placed in each pocket using a die sorting process. Then a batch process operation is performed in which wafer or strip-level alignment and bonding tools are used to join the die in the intermediate die attach carrier in stacks with a second set of die.

Abstract: The present stacked semiconductor packages include a bottom package and a top package. The bottom package includes a substrate, a solder mask layer, a plurality of conductive pillars and a die electrically connected to the substrate. The solder mask layer has a plurality of openings exposing a plurality of pads on the substrate. The conductive pillars are disposed on at least a portion of the pads, and protrude from the solder mask layer.

Abstract: A semiconductor device includes at least a die carried by a substrate, a plurality of bond pads disposed on the die, a plurality of conductive components, and a plurality of bond wires respectively connected between the plurality of bond pads and the plurality of conductive components. The plurality of bond pads respectively correspond to a plurality of signals, and include a first bond pad configured for transmitting/receiving a first signal and a second bond pad configured for transmitting/receiving a second signal. The plurality of conductive components include a first conductive component and a second conductive component. The first conductive component is bond-wired to the first bond pad, and the second conductive component is bond-wired to the second bond pad. The first conductive component and the second conductive component are separated by at least a third conductive component of the plurality of conductive components, and the first signal is asserted when the second signal is asserted.

Abstract: A chip package includes a PCB, a connecting pad fixed on a surface of the PCB and a chip fixed on the connecting pad. The connecting pad includes a first metal film on its surface facing away from the PCB. The chip includes a second metal film formed on its surface opposite to the PCB. The first and the second metal are connected to each other via a eutectic manner.

Abstract: A conductive composition includes a mono-acid hybrid that includes an unprotected, single reactive group. The mono-acid hybrid may include substantially non-reactive groups elsewhere such that the mono-acid hybrid is functional as a chain terminator. Methods and devices using the compositions are also disclosed.

Abstract: A back of a dielectric transparent handle substrate is coated with a blanket conductive film or a mesh of conductive wires. A semiconductor substrate is attached to the transparent handle substrate employing an adhesive layer. The semiconductor substrate is thinned in the bonded structure to form a stack of the transparent handle substrate and the semiconductor interposer. The thinned bonded structure may be loaded into a processing chamber and electrostatically chucked employing the blanket conductive film or the mesh of conductive wires. The semiconductor interposer may be bonded to a semiconductor chip or a packaging substrate employing C4 bonding or intermetallic alloy bonding. Illumination of ultraviolet radiation to the adhesive layer is enabled, for example, by removal of the blanket conductive film or through the mesh so that the transparent handle substrate may be detached. The semiconductor interposer may then be bonded to a packaging substrate or a semiconductor chip.

Abstract: Provided are semiconductor devices and methods of manufacturing the same. the device may include a semiconductor substrate, a first conductive pattern provided in the semiconductor substrate to have a first width at a surface level of the semiconductor substrate, a barrier pattern covering the first conductive pattern and having a second width substantially greater than the first width, a second conductive pattern partially covering the barrier pattern and having a third width substantially smaller than the second width, and an insulating pattern disposed on a sidewall of the second conductive pattern. The second width may be substantially equal to or less than to a sum of the third width and a width of the insulating pattern.