Abstract: Various methods for forming a low profile assembly are described. The low profile assembly may include an integrated circuit. The integrated circuit as well as components associated with the integrated circuit may be positioned below a surface plane of a printed circuit board in which the integrated circuit is located. The integrated circuit may include bond wires configured to electrically connect the integrated circuits to other components. The low profile assembly may include forming various layers over a substrate and later removing some of the layers.

Abstract: A semiconductor chip including through silicon vias (TSVs), wherein the TSVs may be prevented from bending and the method of fabricating the semiconductor chip may be simplified, and a method of fabricating the semiconductor chip. The semiconductor chip includes a silicon substrate having a first surface and a second surface; a plurality of TSVs which penetrate the silicon substrate and protrude above the second surface of the silicon substrate; a polymer pattern layer which is formed on the second surface of the silicon substrate, surrounds side surfaces of the protruding portion of each of the TSVs, and comprises a flat first portion and a second portion protruding above the first portion; and a plated pad which is formed on the polymer pattern layer and covers a portion of each of the TSVs exposed from the polymer pattern layer.

Abstract: In a reflow process, a plurality of solder bumps between a first workpiece and a second workpiece is melted. During a solidification stage of the plurality of solder bumps, the plurality of solder bumps is cooled at a first cooling rate. After the solidification stage is finished, the plurality of solder bumps is cooled at a second cooling rate lower than the first cooling rate.

Abstract: The present disclosure relates to the field of fabricating microelectronic packages, wherein components of the microelectronic packages may have magnetic attachment structures comprising a magnetic component and a metal component. The magnetic attachment structure may be exposed to a magnetic field, which, through the vibration of the magnetic component, can heat the magnetic attachment structure, and which when placed in contact with a solder material can reflow the solder material and attach microelectronic components of the microelectronic package.

Abstract: Articles containing a matrix material and plurality of copper nanoparticles in the matrix material that have been at least partially fused together are described. The copper nanoparticles are less than about 20 nm in size. Copper nanoparticles of this size become fused together at temperatures and pressures that are much lower than that of bulk copper. In general, the fusion temperatures decrease with increasing applied pressure and lowering of the size of the copper nanoparticles. The size of the copper nanoparticles can be varied by adjusting reaction conditions including, for example, surfactant systems, addition rates, and temperatures. Copper nanoparticles that have been at least partially fused together can form a thermally conductive percolation pathway in the matrix material.

Abstract: Various embodiments of mechanisms for forming through a three-dimensional integrated circuit (3DIC) structure are provided. The 3DIC structure includes an interposer bonded to a die and a substrate. The interposer has a conductive structure with through silicon vias (TSVs) connected to a patterned metal pad and a conductive structure on opposite ends of the TSVs. The pattern metal pad is embedded with dielectric structures to reduce dishing effect and has regions over TSVs that are free of the dielectric structures. The conductive structure has 2 or more TSVs. By using a patterned metal pad and 2 or more TSVs, the reliability and yield of the conductive structure and the 3DIC structure are improved.

Abstract: A device is provided. The device may comprise an integrated circuit package. The integrated circuit package may comprise a first layer and a solder mask. The first layer may comprise a top surface wherein the solder mask is disposed on the top surface of the first layer. The solder mask may comprise a vertical edge. The vertical edge may form an angle between the top surface of the first layer and the vertical edge of not less than 90 degrees. The angle may be not less than 120 degrees or not less than 150 degrees.

Abstract: The present invention discloses methods and apparatuses for the separations of IC fabrication and assembling of separated IC components to form complete IC structures. In an embodiment, the present fabrication separation of an IC structure into multiple discrete components can take advantages of dedicated IC fabrication facilities and achieve more cost effective products. In another embodiment, the present chip assembling provides high density interconnect wires between bond pads, enabling cost-effective assembling of small chip components. In an aspect, the present process coats the component surfaces to facilitate the bonding of the bond pads. In another aspect, the present process coats the bond pads with shelled capsules to facilitate the bonding of the bond pads.

Abstract: A method of forming a bump structure includes providing a semiconductor substrate and forming an under-bump-metallurgy (UBM) layer on the semiconductor substrate. The method further includes forming a mask layer on the UBM layer, wherein the mask layer has an opening exposing a portion of the UBM layer. The method further includes forming a copper layer in the opening of the mask layer and removing a portion of the mask layer to form a space between the copper layer and the mask layer. The method further includes performing an electrolytic process to fill the space with a metal layer and removing the mask layer.

Abstract: A method of fabricating a wafer-level chip package is provided. First, a wafer with two adjacent chips is provided, the wafer having an upper surface and a lower surface, and one side of each chip includes a conducting pad on the lower surface. A recess and an isolation layer extend from the upper surface to the lower surface, which the recess exposes the conducting pad. A part of the isolation layer is disposed in the recess with an opening to expose the conducting pad. A conductive layer is formed on the isolation layer and the conductive pad, and a photo-resist layer is spray coated on the conductive layer. The photo-resist layer is exposed and developed to expose the conductive layer, and the conductive layer is etched to form a redistribution layer. After stripping the photo-resist layer, a solder layer is formed on the isolation layer and the redistribution layer.

Abstract: An integrated circuit package system includes a substrate having an opening provided therein, forming a conductor in the opening having a closed end at the bottom, attaching an integrated circuit die over the substrate, and connecting a die interconnect to the integrated circuit die and the closed end of the conductor.

Abstract: A resin-encapsulated semiconductor device includes: a semiconductor element mounted on a die pad portion; a plurality of lead portions disposed so that distal end parts thereof are opposed to the die pad portion; a metal thin wire for connecting an electrode of the semiconductor element to the lead portion; and an encapsulating resin for partially encapsulating those components. A bottom surface part of the die pad portion, and a bottom surface part, an outer surface part, and an upper end part of the lead portion are exposed from the encapsulating resin. A plated layer is formed on the exposed lead bottom surface part and the exposed lead upper end part.

Abstract: A method of forming a chip stack is provided and includes arraying solder pads along a plane of a major surface of a substrate forming walls of electrically insulating material between adjacent ones of the solder pads.

Abstract: A method and apparatus for a conductive pillar structure is provided. A device may be provided, which may include a substrate, a first passivation layer formed over the substrate, a conductive interconnect extending through the first passivation layer and into the substrate, a conductive pad formed over the first passivation layer, and a second passivation layer formed over the interconnect pad and the second passivation layer. A portion of the interconnect pad may be exposed from the second passivation layer. The conductive pillar may be formed directly over the interconnect pad using one or more electroless plating processes. The conductive pillar may have a first and a second width and a first height corresponding to a distance between the first width and the second width.

Abstract: Mechanisms of forming a bond pad structure are provided. The bond pad has a recess region, which is formed by an opening in the passivation layer underneath the bond pad. An upper passivation layer covers at least the recess region of the bond pad to reduce trapping of patterning and/or etching residues in the recess region. As a result, the likelihood of bond pad corrosion is reduced.

Abstract: A semiconductor unit includes a chip having left and right columns of contacts at its front surface. Interconnect pads are provided overlying the front surface of the chip and connected to at least some of the contacts as, for example, by traces or by arrangements including wire bonds. The interconnect pads alone, or the interconnect pads and some of the contacts, provide an array of external connection elements. This array includes some reversal pairs of external connection elements in which the external connection element connected to or incorporating the right contact is disposed to the left of the external connection element incorporating or connected to the left contact. Such a unit may be used in a multi-chip package. The reversed connections simplify routing, particularly where corresponding contacts of two chips are to be connected to common terminals on the package substrate.

Abstract: According to one embodiment, a first core pattern is formed in a wiring portion on a process target film and a second core pattern, which is led out from the first core pattern and includes an opening, is formed in a leading portion on the process target film, a sidewall pattern is formed along an outer periphery of the first core pattern and the second core pattern and a sidewall dummy pattern is formed along an inner periphery of the opening of the second core pattern, the first core pattern and the second core pattern are removed, and the process target film is processed to transfer the sidewall pattern and the sidewall dummy pattern.

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: To form a through-silicon via (TSV) in a silicon substrate without using plating equipment or using sputtering equipment or small metal particles, and form an interlayer connection by stacking a plurality of such silicon substrates, a through hole of a silicon substrate is filled using molten solder itself. In detail, solid solder placed above the through hole of the silicon substrate is molten and the molten solder is guided to and filled in the internal space. A metal layer can be deposited on an internal surface of the through hole beforehand, and also an intermetallic compound (IMC) can be formed in a portion other than the metal layer.

Abstract: An electronic device includes a chip with an integrated electronic component and a terminal made of a first metal material. The device further includes a lead made of a second metal material different from the first metal material. A bonding wire made of a selected one of the first and second metal materials has opposite ends coupled with the terminal and the lead. An interface element having a first layer made of a selected one of the first and second metal materials and a second layer made of an unselected one of the first and second metal materials has the first layer coupled with the bonding wire and the second layer coupled with a component, wherein the component is ether the terminal or the lead.

Abstract: The invention provides a semiconductor device including a substrate, a dielectric layer, a dummy bonding pad, a bonding pad, a redistribution layer, and a metal interconnect. The substrate includes a non-device region and a device region. The dielectric layer is on the non-device region and the device region. The dummy bonding pad is on the dielectric layer of the non-device region. The metal interconnect is in the dielectric layer of the non-device region and connected to the dummy bonding pad. The bonding pad is on the dielectric layer of the device region. The buffer layer is between the bonding pad and the dielectric layer. The buffer layer includes metal, metal nitride, or a combination thereof The redistribution layer is on the dielectric layer and connects the dummy bonding pad and the bonding pad.

Abstract: An electrical connection structure for an integrated circuit chip includes a through via provided in a opening and a laterally adjacent void that are formed in a rear face of a substrate die. A front face of the substrate die includes integrated circuits and a layer incorporating a front electrical interconnect network. The via extends through the substrate die to reach a connection portion of the front electrical interconnect network. An electrical connection pillar made of an electrically conductive material is formed on a rear part of the electrical connection via above the void. A local external protection layer may at least partly cover the electrical connection via and the electrical connection pillar.

Abstract: A wafer level semiconductor device and manufacturing method including providing a semiconductor device wafer substrate having a backside, applying to the backside a conductive metallization layer, and applying to the backside over the conductive metallization layer a protective metal layer of titanium, titanium alloys, nickel, nickel alloys, chromium, chromium alloys, cobalt. cobalt alloys, palladium, and palladium alloys.

Abstract: Disclosed are a flip-chip carrier having individual pad masks (IPMs) and a fabricating method of a MPS-C2 package utilized from the same. The flip-chip carrier primarily comprises a substrate and a plurality of the IPMs. The substrate has a top surface and a plurality of connecting pads on the top surface. The IPMs cover the corresponding connecting pads in one-on-one alignment where each IPM consists of a photo-sensitive adhesive layer on the corresponding connecting pad and a pick-and-place body pervious to light formed on the photo-sensitive adhesive layer. After the photo-sensitive adhesive layers are irradiated by light penetrating through the pick-and-place bodies, the pick-and-place bodies can be pulled out by a pick-and-place process to expose the connecting pads from an encapsulant. The issues of solder bridging and package warpage can easily be solved in conventional MPS-C2 packages.

Abstract: A sensor array package can include a sensor disposed on a first side of a substrate. Signal trenches can be formed along the edges of the substrate and a conductive layer can be deposited in the signal trench and can couple to sensor signal pads. Bond wires can be attached to the conductive layers and can be arranged to be below a surface plane of the sensor. The sensor array package can be embedded in a printed circuit board enabling the bond wires to terminate at other conductors within the printed circuit board.

Abstract: A contact region for a semiconductor substrate is disclosed. Embodiments can include forming a seed metal layer having an exposed solder pad region on the semiconductor substrate and forming a first metal layer on the seed metal layer. In an embodiment, a solderable material, such as silver, can be formed on the exposed solder pad region prior to forming the first metal layer. Embodiments can include forming a solderable material on the exposed solder pad region after forming the first metal layer. Embodiments can also include forming a plating contact region on the seed metal layer, where the plating contact region allows for electrical conduction during a plating process.

Abstract: An electronic unit is produced including at least one electronic component at least partially embedded in an insulating material. A film assembly is provided with at least one conductive layer and a carrier layer. The conductive layer includes openings in the form of holes for receiving bumps, which are connected to contact surfaces of the at least one electronic component. The at least one component is placed on the film assembly such that the bumps engage with the openings of the conductive layer. The at least one component is partially embedded from the side opposite of the bumps into a dielectric layer. The carrier layer of the film assembly is removed such that the surface of the bumps is exposed. A metallization layer is then deposited on the side of the remaining conductive layer having the exposed bumps and so as to produce conductor tracks that overlap with the bumps.

Abstract: The amount of gold required for bonding a semiconductor die to an electronic package is reduced by using a sheet preform tack welded to the package prior to mounting the die. The preform, only slightly larger than a semiconductor die to be attached to the package, is placed in the die bond location and tack welded to the package at two spaced locations.

Abstract: A method includes providing a semiconductor chip having a first main surface and a second main surface. A semiconductor chip is placed on a carrier with the first main surface of the semiconductor chip facing the carrier. A first layer of solder material is provided between the first main surface and the carrier. A contact clip including a first contact area is placed on the semiconductor chip with the first contact area facing the second main surface of the semiconductor chip. A second layer of solder material is provided between the first contact area and the second main surface. Thereafter, heat is applied to the first and second layers of solder material to form diffusion solder bonds between the carrier, the semiconductor chip and the contact clip.

Abstract: A front-end method of fabricating nickel plated caps over copper bond pads used in a memory device. The method provides protection of the bond pads from an oxidizing atmosphere without exposing sensitive structures in the memory device to the copper during fabrication.

Abstract: Provided are a semiconductor device and a method of manufacturing the semiconductor device. In order to improve reliability by solving a problem of conductivity that may occur when an air spacer structure that may reduce a capacitor coupling phenomenon between a plurality of conductive lines is formed, there are provided a semiconductor device including: a substrate having an active region; a contact plug connected to the active region; a landing pad spacer formed to contact a top surface of the contact plug; a contact conductive layer formed to contact the top surface of the contact plug and formed in a space defined by the landing pad spacer; a metal silicide layer formed on the contact conductive layer; and a landing pad connected to the contact conductive layer in a state in which the metal silicide layer is disposed between the landing pad and the contact conductive layer, and a method of manufacturing the semiconductor device.

Abstract: To reduce the radio frequency (RF) losses associated with high RF loss plating, such as, for example, Nickel/Palladium/Gold (Ni/Pd/Au) plating, an on-die passive device, such as a capacitor, resistor, or inductor, associated with a radio frequency integrated circuit (RFIC) is placed in an RF upper signal path with respect to the RF signal output of the RFIC. By placing the on-die passive device in the RF upper signal path, the RF current does not directly pass through the high RF loss plating material of the passive device bonding pad.

Abstract: A method including forming a contact pad array on an integrated circuit substrate, the contact pad array including a first plurality of contact pads and a second plurality of contact pads, wherein an accessible area of each of the first plurality of contact pads is different than an accessible area of each of the second plurality of contact pads; and depositing solder on the accessible area of the contact pads. An apparatus including an integrated circuit substrate including a body having a nonplanar shape and a surface including a first plurality of contact pads and a second plurality of contact pads, wherein an accessible area of each of the first plurality of contact pads is different than an accessible area of each of the second plurality of contact pads.

Abstract: A bumped substrate is optimized to be flat post reflow. By producing the bumped substrate to be flat post reflow, device reliability is assured. More particularly, the transistor shift associated with warped substrates is avoided. Further, by producing a flat bumped substrate post reflow, reliability in the flip chip interconnections is assured as compared to the undesirable open circuits associated with warped substrates.

Abstract: A differential port and a method of arranging the differential port are described. The method includes arranging a first electrode to receive a drive signal, and arranging a second electrode to receive a guard signal, the guard signal having a different phase than the drive signal and the first electrode and the second electrode having a gap therebetween. The method also includes disposing a signal line from the first electrode to drive a radio frequency (RF) device.

Abstract: A package for a plurality of semiconductor devices having: an electrical interconnect structure, comprising: an electrical interconnect structure; and an active device structure, comprising the plurality of semiconductor devices on an active device substrate. The electrical interconnect structure is bonded to the active device structure and the electrical interconnect structure provides electrical interconnection among the semiconductor devices.

Abstract: A semiconductor package and a fabrication method thereof are disclosed, which is characterized in that a solder material is used to bond an LED chip and a substrate so as to provide a thick joint between the substrate and the LED chip and hence reduce stresses generated between the LED chip and the substrate due to their CTE mismatch, thereby preventing delamination from occurring between the LED chip and the substrate after a reliability test.

Abstract: A two-layer structure bump including a first bump layer of a bulk body of a first conductive metal, which is any of gold, copper, and nickel, formed on a substrate and a second bump layer of a sintered body of a powder of a second conductive metal, which is any of gold and silver, formed on the first bump layer. The bulk body composing the first bump layer is formed through any of plating, sputtering, or CVD. The sintered body composing the second bump layer is formed by sintering the powder of the second conductive metal having a purity of not lower than 99.9 wt % and an average particle diameter of 0.005 ?m to 1.0 ?m. The second bump layer has a Young's modulus 0.1 to 0.4 times that of the first bump layer.

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: In accordance with an embodiment of the present invention, a method of forming a semiconductor device includes forming a seed layer over a dielectric layer and a patterned resist layer over the seed layer. Next, metal lines are formed on regions of the seed layer not covered by the patterned resist layer. The patterned resist layer is removed using a plasma process, which involves using an oxidizing species and a reducing species in the plasma. The reducing species substantially prevents the oxidation of the metal lines and the seed layer during the plasma process.

Abstract: Some embodiments include semiconductor processing methods in which a copper barrier is formed to be laterally offset from a copper component, and in which nickel is formed to extend across both the barrier and the component. The barrier may extend around an entire lateral periphery of the component, and may be spaced from the component by an intervening ring of electrically insulative material. The copper component may be a bond pad or an interconnect between two levels of metal layers. Some embodiments include semiconductor constructions in which nickel extends across a copper component, a copper barrier is laterally offset from the copper component, and an insulative material is between the copper barrier and the copper component.

Abstract: A method for manufacturing a chip arrangement in accordance with various embodiments may include: placing a chip on a carrier within an opening of a metal structure disposed over the carrier; fixing the chip to the metal structure; removing the carrier to thereby expose at least one contact of the chip; and forming an electrically conductive connection between the at least one contact of the chip and the metal structure.

Abstract: A fabrication method of a chip package includes the following steps. A wafer structure having a wafer and a protection layer is provided. The first opening of the wafer is aligned with and communicated with the second opening of the protection layer. A first insulating layer having a first thickness is formed on a conductive pad exposed from the second opening, and a second insulating layer having a second thickness is formed on a first sidewall of the protection layer surrounding the second opening and a second sidewall of the wafer surrounding the first opening. The first and second insulating layers are etched, such that the first insulating layer is completely removed, and the second thickness of the second insulating layer is reduced.

Abstract: To reduce radio frequency (RF) losses during operation of a radio frequency integrated circuit (RFIC) module, the RFIC module is fabricated such that at least one of an edge of the wirebond pad on the copper trace and a sidewall of the copper trace is free from high-resistivity plating material. The unplated portion provides a path for the RF current to flow around the high-resistivity material, which reduces the RF signal loss associated with the high resistivity plating material.

Abstract: A method of fabricating a microelectronic package can include mounting a microelectronic element to a substrate with a joining material. The mounting can include bonding a front surface of the microelectronic element to a first surface of the substrate with a joining material, and joining contacts arranged within a contact-bearing region of the front surface of the microelectronic element with corresponding substrate contacts at the substrate first surface, the joining creating electrical contact between the microelectronic element and the substrate. The method can also include forming an underfill between the substrate first surface and the contact-bearing region of the front surface of the microelectronic element, the underfill reinforcing the joints between the contacts and the substrate contacts, the joining material having a Young's modulus less than 75% of a Young's modulus of the underfill.

Abstract: A method for forming a chip package, in which a substrate has a plurality of conducting pads located below its lower surface, and a dielectric layer located between the conducting pads. A hole is formed extending from the upper surface of the substrate towards the conducting pads. After the hole is formed, a trench is formed extending from the upper surface towards the lower surface of the substrate, with the trench connecting with the hole. An insulating layer is formed on a sidewall of the trench and a sidewall and a bottom of the hole, and a portion of the insulating layer and a portion of the dielectric layer are removed to expose a portion of the conducting pads. A conducting layer is formed on the sidewall of the trench and the sidewall and the bottom of the hole, electrically contacting with the conducting pads.

Abstract: An integrated circuit package system including: providing an integrated circuit die, forming a first layer over the integrated circuit die, forming a bridge on and in the first layer, forming a second layer on the first layer, and forming bump pads on and in the second layer, the bump pads connected to ends of the bridge.

Abstract: In accordance with an embodiment of the present invention, a semiconductor device includes a first bond pad disposed at a first side of a substrate. The first bond pad includes a first plurality of pad segments. At least one pad segment of the first plurality of pad segments is electrically isolated from the remaining pad segments of the first plurality of pad segments.

Abstract: Systems, methods and/or techniques for mushroom shaped bump on repassivation are described. A method of forming a chip scale package may include applying a first photoresist layer over a semiconductor wafer, developing away a portion of the first photoresist layer to define a cylindrically shaped template with substantially vertical side walls, and plating metal at least partially within the template to form a bump. The bump may include a first cylindrical base portion, a cap, and a lip formed by a portion of the cap that extends horizontally outward beyond the first cylindrical base portion. The cap and lip may be formed such that a vertical distance exists between the lip and the semiconductor wafer, defining an intrusion area. The method may include removing excess portions of the first photoresist layer, including portions residing in the intrusion area, to isolate the bump.

Abstract: A method and structure for bump-on-trace bonding is provided. In an embodiment traces to be used for bump-on-trace (BOT) bonding are protected during a pre-solder treatment. The pre-solder treatment improves the adhesion between the exposed traces (e.g., the non-BOT traces) and a solder resist layer.