Abstract: A solder ball contact and a method of making a solder ball contact includes: a first insulating layer with a via formed on an integrated circuit (IC) chip and a metal pad; an under bump metallurgy (UBM) structure disposed within the via and on a portion of the first insulating layer, surrounding the via; a second insulating layer formed on an upper surface of an outer portion of the UBM structure that is centered on the via; and a solder ball that fills the via and is disposed above an upper surface of an inner portion of the UBM structure that contacts the via, in which the UBM structure that underlies the solder ball is of a greater diameter than the solder ball.

Abstract: An embedded package that may be realized by surrounding a semiconductor chip (or a semiconductor die) in a package substrate. A semiconductor chip of an embedded package may be electrically connected to external connection terminals through interconnection wires instead of bumps, and the interconnection wires may be formed using a wire bonding process. A high reliability embedded package results.

Abstract: Some embodiments of the invention include a connecting structure between a support and at least one die attached to the support. The die includes a number of die bond pads on a surface of the die. The connecting structure includes a plurality of via and groove combinations. Conductive material is formed in the via and groove combinations to provide connection between the die bond pads and bond pads on the support. Other embodiments are described and claimed.

Abstract: A package structure includes a micro-electromechanical element having a plurality of electrical contacts; a package layer enclosing the micro-electromechanical element and the electrical contacts, with a bottom surface of the micro-electromechanical element exposed from a lower surface of the package layer; a plurality of bonding wires embedded in the package layer, each of the bonding wires having one end connected to one of the electrical contacts, and the other end exposed from the lower surface of the package layer; and a build-up layer structure provided on the lower surface of the package layer, the build-up layer including at least one dielectric layer and a plurality of conductive blind vias formed in the dielectric layer and electrically connected to one ends of the bonding wires. The package structure is easier to accurately control the location of an external electrical contact, and the compatibility of the manufacturing procedures is high.

Abstract: A semiconductor device includes a lower structure, an insulation layer, metal contacts, a bridge and a metal pad. The lower structure has a metal wiring. An insulation layer is formed on the lower structure. The metal contacts penetrate the insulation layer to be connected to the metal wiring. The bridge is provided in the insulation layer, the bridge connecting the metal contacts to one another. The metal pad is provided on the insulation layer, the metal pad making contact with the metal contacts.

Abstract: An improved wafer level chip scale packaging technique is described which does not use an encapsulated via to connect between a redirection layer and a pad within the pad ring on the semiconductor die. In an embodiment, a first dielectric layer is formed such that it terminates on each die within the die's pad ring. Tracks are then formed in a conductive layer which contact one of the pads and run over the edge of an opening onto the surface of the first dielectric layer. These tracks may be used to form an electrical connection between the pad and a solder ball.

Abstract: A package component is free from active devices therein. The package component includes a substrate, a through-via in the substrate, a top dielectric layer over the substrate, and a metal pillar having a top surface over a top surface of the top dielectric layer. The metal pillar is electrically coupled to the through-via. A diffusion barrier is over the top surface of the metal pillar. A solder cap is disposed over the diffusion barrier.

Abstract: A contiguous layer of graphene is formed on exposed sidewall surfaces and a topmost surface of a copper-containing structure that is present on a surface of a substrate. The presence of the contiguous layer of graphene on the copper-containing structure reduces copper oxidation and surface diffusion of copper ions and thus improves the electromigration resistance of the structure. These benefits can be obtained using graphene without increasing the resistance of copper-containing structure.

Abstract: A chip package includes a substrate having an upper and a lower surface and including: at least a first contact pad; a non-optical sensor chip disposed overlying the upper surface, wherein the non-optical sensor chip includes at least a second contact pad and has a first length; a protective cap disposed overlying the non-optical sensor chip, wherein the protective cap has a second length, an extending direction of the second length is substantially parallel to that of the first length, and the second length is shorter than the first length; an IC chip disposed overlying the protective cap, wherein the IC chip includes at least a third contact pad and has a third length, and an extending direction of the third length is substantially parallel to that of the first length; and bonding wires forming electrical connections between the substrate, the non-optical sensor chip, and the IC chip.

Abstract: An integrated circuit package system that includes: providing a first package including a first package first device and a first package second device both adjacent a first package substrate; and mounting and electrically interconnecting a second package over an electrical interconnect array formed on a substrate of the first package second device.

Abstract: A semiconductor device (5) for radio frequency applications has a semiconductor chip (1) with an integrated circuit accommodated in a radio frequency package. Inside bumps (2) comprise inside contacts between the semiconductor chip (1) and a redistribution substrate (3). The inside bumps (2) have a metallic or plastic core (6) and a coating layer (7) of a noble metal.

Abstract: A die includes a metal pad, a passivation layer, and a patterned buffer layer over the passivation layer. The patterned buffer layer includes a plurality of discrete portions separated from each other. An under-bump-metallurgy (UBM) is formed in an opening in the patterned buffer layer and an opening in the passivation layer. A metal bump is formed over and electrically coupled to the UBM.

Abstract: A semiconductor device includes a bump structure over a pad region. The bump structure includes a copper layer and a lead-free solder layer over the copper layer. The lead-free solder layer is a SnAg layer, and the Ag content in the SnAg layer is less than 1.6 weight percent.

Abstract: A multi-die package includes a first semiconductor die and a second semiconductor die each having an upper surface with a plurality of bond pads disposed thereon. The upper surface of the second semiconductor die may be substantially coextensive with the upper surface of the first semiconductor die and extend substantially along a plane. The multi-die package also includes a plurality of bonding wires each coupling one of the bond pads on the upper surface of the first semiconductor die to a corresponding one of the bond pads on the upper surface of the second semiconductor die. A bonding wire of the plurality of bonding wires has a kink disposed at a height above the plane, a first hump disposed between the first semiconductor die and the kink, and a second hump disposed between the second semiconductor die and the kink.

Abstract: Methods and apparatuses for wafer level packaging (WLP) of semiconductor devices are disclosed. A contact pad of a circuit may be connected to a solder bump by way of a post passivation interconnect (PPI) line and a PPI pad. The PPI pad may comprise a hollow part and an opening. The PPI pad may be formed together with the PPI line as one piece. The hollow part of the PPI pad can function to control the amount of solder flux used in the ball mounting process so that any extra amount of solder flux can escape from an opening of the solid part of the PPI pad. A solder ball can be mounted to the PPI pad directly without using any under bump metal (UBM) as a normal WLP package would need.

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: One embodiment provides a semiconductor package by forming a redistribution layer extending from a bonding pad of a semiconductor chip using a photoresist pattern plated with the seed layer. Fabrication of the semiconductor package is relatively simple thereby shortening a manufacturing time and reducing the manufacturing cost, and which can increase an adhered area of input/output terminals and can prevent delamination by connecting and welding the input/output terminals to a pair of redistribution layers.

Abstract: Provided is a semiconductor device capable of increasing the number of signals. A semiconductor device according to an embodiment of the invention includes memories; a controller that designates addresses of the memories; a mounting board having lines formed thereon, the lines connecting the controller with the memories; and a first ball group that connects the controller with the lines of the mounting board. A plurality of address lines formed on the mounting board includes an address line formed of a front surface wiring layer, and an address line formed of a back surface wiring layer. In each of the front surface wiring layer and the back surface wiring layer, each of the address lines from first balls of the first ball group is routed in order from a first memory to a fourth memory.

Abstract: A semiconductor device of the invention includes a first wiring layer including a signal wiring line formed therein, and a second wiring layer stacked on the first wiring layer and including a power-supply plane and/or ground plane formed therein, the power-supply plane or the ground plane is not formed at least within a part of the region of the second wiring layer facing the signal wiring line of the first wiring layer.

Abstract: Embodiments of the present disclosure provide an apparatus including a semiconductor die having a plurality of integrated circuit devices, a pad structure electrically coupled to at least one integrated circuit device of the plurality of integrated circuit devices via an interconnect layer, an electrically insulative layer disposed on the interconnect layer, a first shielding structure disposed in the electrically insulative layer and electrically coupled to the pad structure, an under-ball metallization (UBM) structure electrically coupled to the first shielding structure, and a solder bump electrically coupled to the UBM structure, the solder bump comprising a solder bump material capable of emitting alpha particles, wherein the first shielding structure is positioned between the solder bump and the plurality of integrated circuit devices to shield the plurality of integrated circuit devices from the alpha particles. Other embodiments may be described and/or claimed.

Abstract: A stack of semiconductor chips, a semiconductor device, and a method of manufacturing are disclosed. The stack of semiconductor chips may comprise a first chip of the stack, a second chip of the stack over the first chip, conductive bumps, a homogeneous integral underfill material, and a molding material. The conductive bumps may extend between an upper surface of the first chip and a lower surface of the second chip. The homogeneous integral underfill material may be interposed between the first chip and the second chip, encapsulate the conductive bumps, and extend along sidewalls of the second chip. The homogeneous integral underfill material may have an upper surface extending in a direction parallel to an upper surface of the second chip and located adjacent the upper surface of the second chip.

Abstract: An embodiment of the invention provides a chip package which includes: a carrier substrate; a semiconductor substrate having an upper surface and a lower surface, disposed overlying the carrier substrate; a device region or sensing region located on the upper surface of the semiconductor substrate; a conducting pad located on the upper surface of the semiconductor substrate; a conducting layer electrically connected to the conducting pad and extending from the upper surface of the semiconductor substrate to a sidewall of the semiconductor substrate; and an insulating layer located between the conducting layer and the semiconductor substrate.

Abstract: A surface mount semiconductor device is assembled by positioning an array of semiconductor dies with an array of metallic ground plane members between and beside the semiconductor dies. The arrays of dies and ground plane members are encapsulated in a molding compound. A redistribution layer is formed on the arrays of dies and ground plane members. The redistribution layer has an array of sets of redistribution conductors within a layer of insulating material. The redistribution conductors interconnect electrical contacts of the dies with external electrical contact elements of the device. As multiple devices are formed at the same time, adjacent devices are separated (singulated) by cutting along saw streets between the dies. The molding compound is interposed between tie bars of the ground plane members and the insulating material of the redistribution layer in the saw streets, and at the side surfaces of the singulated devices.

Abstract: A system-level packaging method includes providing a packaging substrate having a first functional surface and a second surface with wiring arrangement within the packaging substrate and between the first functional surface and the second surface. The method also includes forming at least two package layers on the first functional surface of the packaging substrate, wherein each package layer is formed by subsequently forming a mounting layer, a sealant layer, and a wiring layer. Further, the method includes forming a top sealant layer and planting connection balls on the second functional surface of the packaging substrate.

Abstract: An array of bonding pads including a set of reactive materials is provided on a first substrate. The set of reactive materials is selected to be capable of ignition by magnetic heating induced by time-dependent magnetic field. The magnetic heating can be eddy current heating, hysteresis heating, and/or heating by magnetic relaxation processes. An array of solder balls on a second substrate is brought to contact with the array of bonding pads. A reaction is initiated in the set of magnetic materials by an applied magnetic field. Rapid release of heat during a resulting reaction of the set of reactive materials to form a reacted material melts the solder balls and provides boding between the first substrate and the second substrate. Since the magnetic heating can be localized, the heating and warpage of the substrate can be minimized during the bonding process.

Abstract: A 3D system-level packaging method includes providing a packaging substrate, forming a glue layer on the substrate, and attaching a first chip layer at an opposite side of a functional surface of the first chip layer on the packaging substrate through the glue layer. The method also includes forming a first sealant layer on the packaging substrate at a same side attached with the first chip layer and exposing bonding pads of the first chip layer. The method also includes forming first vias in the first sealant layer, forming first vertical metal wiring in the first vias, and forming a first horizontal wiring layer on the sealant layer interconnecting the first chip layer and the first vertical metal wiring. Further, the method includes forming a plurality of package layers on the first sealant layer, and each of the plurality of package layers includes a chip layer, a sealant layer covering the chip layer, and vertical metal wiring and a horizontal wiring layer interconnecting adjacent package layers.

Abstract: A 3D system-level packaging method includes providing a packaging substrate having a first functional surface and a second surface with wiring arrangement within the packaging substrate and between the first functional surface and the second surface. The method also includes forming at least one flip package layer on the first functional surface of the packaging substrate and forming at least one wiring and package layer on the flip package layer. The flip package layer is formed by subsequently forming a flip mounting layer, an underfill, a sealant layer, and a wiring layer; and the wiring and package layer is formed by subsequently forming a straight mounting layer, a sealant layer, and a wiring layer. Further, the method includes planting connection balls on the second functional surface of the packaging substrate.

Abstract: Structure and methods of forming stacked semiconductor chips are described. In one embodiment, a method of forming a semiconductor chip includes forming an opening for a through substrate via from a top surface of a first substrate. The sidewalls of the opening are lined with an insulating liner and the opened filled with a conductive fill material. The first substrate is etched from an opposite bottom surface to form a protrusion, the protrusion being covered with the insulating liner. A resist layer is deposited around the protrusion to expose a portion of the insulating liner. The exposed insulating liner is etched to form a sidewall spacer along the protrusion.

Abstract: An integrated circuit package including a semiconductor die and a flexible circuit (flex circuit), and a method for forming the integrated circuit package. The flex circuit can include a direct connect pad which is not electrically coupled to an active trace, a blind via electrically coupled to the direct connect pad, and a semiconductor die having a bond pad which is electrically coupled to the direct connect pad using a conductor. The bond pad, the conductor, the direct connect pad, and the blind via can all be vertically aligned, each with the other.

Abstract: Provided are electrical interconnections and methods for fabricating the same. The electrical interconnection may include a substrate including a bonding pad, a solder ball electrically connected to the bonding pad, a solder supporter on the bonding pad, a portion of the solder ball filling the solder supporter, and a metal layer between the bonding pad and the solder supporter, the metal layer having an ionization tendency lower than the bonding pad.

Abstract: A semiconductor device is provided, which comprises a first semiconductor package, a second semiconductor package, and a connection structure. The first semiconductor package includes a first substrate. The first substrate includes a first region and a second region. The second semiconductor package is mounted on the first semiconductor package. The connection structure electrically connects the second semiconductor package and the first semiconductor package. The connection structure comprises first connection patterns at the first region. The first connection patterns provide a data signal at the first region. The connection structure further comprises second connection patterns at the second region. The second connection patterns provide a control/address signal at the second region. A number of the second connection patterns is less than a number of the first connection patterns.

Abstract: A method and structures are provided for implementing decoupling capacitors within a DRAM TSV stack. A DRAM is formed with a plurality of TSVs extending completely through the substrate and filled with a conducting material. A layer of glass is grown on both the top and bottom of the DRAM providing an insulator. A layer of metal is grown on each glass layer providing a conductor. The metal and glass layers are etched through to TSVs with a gap provided around the perimeter of via pads. A respective solder ball is formed on the TSVs to connect to another DRAM chip in the DRAM TSV stack. The metal layers are connected to at least one TSV by one respective solder ball and are connected to a voltage source and a dielectric is inserted between the metal layers in the DRAM TSV stack to complete the decoupling capacitor.

Abstract: In semiconductor integrated circuit devices for vehicle use, an aluminum pad on a semiconductor chip and an external device are coupled to each other by wire bonding using a gold wire for the convenience of mounting. Such a semiconductor integrated circuit device, however, causes a connection failure due to the interaction between aluminum and gold in use for a long time at a relatively high temperature (about 150 degrees C.). A semiconductor integrated circuit device can include a semiconductor chip as a part of the device, an electrolytic gold plated surface film (gold-based metal plated film) provided over an aluminum-based bonding pad on a semiconductor chip via a barrier metal film, and a gold bonding wire (gold-based bonding wire) for interconnection between the plated surface film and an external lead provided over a wiring board (wiring substrate).

Abstract: Apparatuses for interconnecting integrated circuit dies. A first set of single-ended transmitter circuits are included on a first die. The transmitter circuits are impedance matched and have no equalization. A first set of single-ended receiver circuits are included on a second die. The receiver circuits have no termination and no equalization. Conductive lines are coupled between the first set of transmitter circuits and the first set of receiver circuits. The lengths of the conductive lines are matched. The first die, the first set of single-ended transmitter circuits, the second die, the first set of single ended receiver circuits and the conductive lines are disposed within a first package. A second set of single-ended transmitter circuits are included on the first die. The transmitter circuits are impedance matched and have no equalization. Data transmitted from the second set of transmitter circuits is transmitted according to a data bus inversion (DBI) scheme.

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: An embodiment 3DIC device includes a semiconductor chip, a die, and a polymer. The semiconductor chip includes a semiconductor substrate, wherein the semiconductor substrate comprises a first edge, and a low-k dielectric layer over the semiconductor substrate. The die is disposed over and bonded to the semiconductor chip. The polymer is molded onto the semiconductor chip and the die. The polymer includes a portion level with the low-k dielectric layer, wherein the portion of the polymer comprises a second edge vertically aligned to the first edge of the semiconductor substrate and a third edge contacting the low-k dielectric layer, wherein the second and the third edges are opposite edges of the portion of the polymer.

Abstract: A multi-die package includes a first semiconductor die and a second semiconductor die each having an upper surface with a plurality of bond pads positioned thereon. The multi-die package also includes a plurality of bonding wires each coupling one of the bond pads on the upper surface of the first semiconductor die to a corresponding one of the bond pads on the upper surface of the second semiconductor die. A bonding wire of the plurality of bonding wires includes a first portion extending upward from one of the second plurality of bond pads substantially along a z-axis and curving outward substantially along x and y axes in a direction towards the first semiconductor die. The bonding wire also includes a second portion coupled to the first portion and extending from the first portion downward to one of the first plurality of bond pads on the upper surface of the first semiconductor die.

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: In flip chip attach of electronic components, underfill is filled between the component and the substrate to alleviate, for example, thermal stress. In electronic component mounting using copper pillars conducted so far, filler contained in the underfill may cause separation in the process of heating and curing the resin. Disclosed is plating the surfaces of the copper pillars with solder. Mobilization of the filler charged in the underfill due to electric fields produced by local cells that are developed upon contact between dissimilar metals, is suppressed, and occurrence of crack at connection portions is obviated. Thus, connection reliability is increased.

Abstract: A through wire interconnect for a semiconductor substrate includes a via extending through the semiconductor substrate from the first side to the second side thereof; a wire in the via having a first end with a bonded connection to the substrate contact and a second end proximate to the second side of the semiconductor substrate; a dielectric material in the via configured to electrically insulate the wire from the semiconductor substrate; a bonding member bonded to the first end of the wire and to the substrate contact configured to secure the wire to the substrate contact; and a contact on the second end of the wire.

Abstract: A semiconductor package includes terminals extending from a bottom surface of the semiconductor package, and a layer of interconnection routings disposed within the semiconductor package. Each terminal includes a first plated section, a second plated section, and a portion of a sheet carrier from which the semiconductor package is built upon, wherein the portion is coupled between the first and second plated sections. Each interconnection routing is electrically coupled with a terminal and can extend planarly therefrom. The semiconductor package also includes at least one die coupled with the layer of interconnection routings. In some embodiments, the semiconductor package also includes at least one intermediary layer, each including a via layer and an associated routing layer. The semiconductor package includes a locking mechanism for fastening a package compound with the interconnection routings and the terminals.

Abstract: A molding material used to fabricate a semiconductor package, a method of fabricating the molding composition, and a semiconductor package obtained by using the molding composition are disclosed. A molding composition includes a molding resin material, a filler, and a water absorption material coated on a surface of the filler, such that an amount of external moisture penetrating into the semiconductor package may be diminished. A semiconductor package includes a substrate, at least one chip mounted on the substrate, a connecting portion electrically connecting the at least one chip and the substrate, and a molding portion encapsulating the at least one chip on the substrate, wherein the molding portion includes a molding composition including a molding resin material, a filler, and a water absorption material coated on a surface of the filler, such that an amount of external moisture penetrating into the semiconductor package may be diminished.

Abstract: Protection of a solder ball joint is disclosed in which the solder ball joint is located below the surface level of the encapsulating buffer layer. The buffering layer is etched to expose one or more electrode posts, each of which may be made up of a single column or multiple columns. A top layer resulting either from a top conductive cap or a plating layer around the electrode posts also lies below the buffer layer. When the solder ball is placed onto the posts, the solder/ball joint is protected in a position below the surface of the buffer layer, while still maintaining an electrical connection between the various solder balls and their associated or capping/plating material, electrode posts, wiring layers, and circuit layers. Therefore, the entire ball joint is protected from direct stress.

Abstract: A semiconductor package includes terminals, each having an exposed surface that is flush with a bottom surface of the semiconductor package, and a layer of interconnection routings disposed within the semiconductor package. At least one interconnection routing is electrically coupled with a terminal and extends planarly therefrom. The semiconductor package also includes at least one die coupled with the layer of interconnection routings. In some embodiments, the semiconductor package also includes one or more additional intermediary layers. Each intermediary layer includes a via layer and an associated routing layer. The associated routing layer includes associated routings. At least one associated routing is electrically coupled with a terminal and extends planarly therefrom. Each via layer couples two routing layers. The semiconductor package also includes a locking mechanism for fastening a package compound with the interconnection routings and the terminals.

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: A wiring board and a semiconductor package are provided. The wiring board includes: a metal core including a first surface and a second surface opposite the first surface; a first buildup portion and a second buildup portion including an insulating layer and a pad pattern sequentially stacked, the first and second buildup portions being provided on the first surface and the second surface, respectively; a mask pattern including an opening exposing the pad pattern, the mask pattern being provided on the second buildup portion; and a bather pattern in an area in which a region of the metal core which overlaps with the pad pattern of the second buildup portion is removed, wherein a minimum width of an outer circumference of the barrier pattern is greater than a maximum width of the pad pattern of the second buildup portion.

Abstract: A semiconductor device has an interposer mounted over a carrier. The interposer includes TSV formed either prior to or after mounting to the carrier. An opening is formed in the interposer. The interposer can have two-level stepped portions with a first vertical conduction path through a first stepped portion and second vertical conduction path through a second stepped portion. A first and second semiconductor die are mounted over the interposer. The second die is disposed within the opening of the interposer. A discrete semiconductor component can be mounted over the interposer. A conductive via can be formed through the second die or encapsulant. An encapsulant is deposited over the first and second die and interposer. A portion of the interposer can be removed to that the encapsulant forms around a side of the semiconductor device. An interconnect structure is formed over the interposer and second die.

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: A die-on-die assembly has a first die (10) and a second die (50). The first die (10) has a first contact extension (28,42) and a peg (32,44,45) extending a first height above the first die. The second die (50) has a second contact extension (68) connected to the first contact extension and has a containing feature (62) extending a second height above the second die surrounding the peg. The peg extends past the containing feature. Because the peg extends past the containing feature, lateral movement between the first and second die can cause the peg to come in contact with and be constrained by the containing feature. The peg and containing feature are thus useful in constraining movement between the first and second die.

Abstract: The present invention involves a method of providing an integrated circuit package having a substrate with a vent opening. The integrated circuit package includes a substrate having an opening and an integrated circuit mounted to the substrate. An underfill material is dispensed between the substrate and the integrated circuit.