Abstract: A three-dimensional interconnect includes a first substrate bonded to a second substrate, the first substrate including a device layer and a bulk semiconductor layer, a metal pad disposed on the second substrate, an electrically insulating layer disposed between the first and second substrates. The structure has a via-hole extending through the device layer, the bulk semiconductor layer and the electrically insulating layer to the metal pad on the second substrate. The structure has a dielectric coating on a sidewall of the via-hole, and a plasma-treated region of the metal pad disposed on the second substrate. The structure includes a via metal monolithically extending from the plasma-treated region of the metal pad through the via-hole and electrically interconnecting the device layer of the first substrate to the metal pad of the second substrate.

Abstract: One aspect of the present invention is a method of processing a substrate. In one embodiment, the method comprises forming an electrical conductor on or in the substrate by providing a mixture comprising metal particles and an electroless deposition solution and electrolessly depositing a metal matrix and co-depositing the metal particles. In another embodiment, the method comprises forming an electrical conductor on or in the substrate by providing a mixture comprising metal particles and an electrochemical plating solution and electrochemically plating a metal matrix and co-depositing the metal particles. Another aspect of the present invention is a mixture for the formation of an electrical conductor on or in a substrate. Another aspect of the present invention is an electronic device.

Abstract: Embodiments of a semiconductor wafer having wafer-level die attach metallization on a back-side of the semiconductor wafer, resulting semiconductor dies, and methods of manufacturing the same are disclosed. In one embodiment, a semiconductor wafer includes a semiconductor structure and a front-side metallization that includes front-side metallization elements for a number of semiconductor die areas. The semiconductor wafer also includes vias that extend from a back-side of the semiconductor structure to the front-side metallization elements. A back-side metallization is on the back-side of the semiconductor structure and within the vias. For each via, one or more barrier layers are on a portion of the back-side metallization that is within the via and around a periphery of the via. The semiconductor wafer further includes wafer-level die attach metallization on the back-side metallization other than the portions of the back-side metallization that are within the vias and around the peripheries of the vias.

Abstract: A higher aspect ratio for upper level metal interconnects is described for use in higher frequency circuits. Because the skin effect reduces the effective cross-sectional area of conductors at higher frequencies, various approaches are described to reduce the effective RC delay in interconnects.

Abstract: A method of manufacture of an integrated circuit packaging system includes: providing a substrate; mounting an integrated circuit over the substrate; forming an encapsulation over the integrated circuit, the encapsulation having an encapsulation interior sidewall; forming a peripheral non-horizontal conductive plate directly on the encapsulation interior sidewall; and forming a peripheral vertical conductor directly on the peripheral non-horizontal conductive plate and the substrate.

Abstract: A wafer structure includes a first wafer stack and a first bonding layer disposed on the first wafer stack. The wafer structure further includes a second wafer stack that includes a first surface and a second surface opposing the first surface. A second bonding layer is disposed on the second surface and is in contact with the first bonding layer. The second wafer stack comprises through-silicon-vias (TSVs) that extend from the first surface to the second bonding layer. A seed layer is disposed on the first surface and is in contact with the TSVs.

Abstract: Present embodiments relate to a semiconductor device having a backside redistribution layer and a method for forming such a layer. Specifically, one embodiment includes providing a substrate comprising a via formed therein. The substrate has a front side and a backside. The embodiment may further include forming a trench on the backside of the substrate, disposing an insulating material in the trench, and forming a trace over the insulating material in the trench.

Abstract: A package for a microelectronic element, such as a semiconductor chip, has a dielectric mass overlying the package substrate and microelectronic element and has top terminals exposed at the top surface of the dielectric mass. Traces extending along edge surfaces of the dielectric mass desirably connect the top terminals to bottom terminals on the package substrate. The dielectric mass can be formed, for example, by molding or by application of a conformal layer.

Abstract: An integrated structure with a silicon-through via includes a substrate, a through-silicon via penetrating the substrate, a conductive protective structure surrounding the through-silicon via and a first and a second conductive dummy patterns with different shapes disposed between the through-silicon via and the conductive protective structure.

Abstract: The present invention provides a semiconductor device, a semiconductor package and a semiconductor process. The semiconductor process includes the following steps: (a) providing a semiconductor wafer having a first surface, a second surface and a passivation layer; (b) applying a first laser on the passivation layer to remove a part of the passivation layer and expose a part of the semiconductor wafer; (c) applying a second laser, wherein the second laser passes through the exposed semiconductor wafer and focuses at an interior of the semiconductor wafer; and (d) applying a lateral force to the semiconductor wafer. Whereby, the cutting quality is ensured.

Abstract: A chip package and a fabrication method thereof are provided. The chip package includes a semiconductor substrate, having a first surface and an opposing second surface. A spacer is disposed under the second surface of the semiconductor substrate and a cover plate is disposed under the spacer. A recessed portion is formed adjacent to a sidewall of the semiconductor substrate, extending from the first surface of the semiconductor substrate to at least the spacer. Then, a protection layer is disposed over the first surface of the semiconductor substrate and in the recessed portion.

Abstract: A coreless pin-grid array (PGA) substrate includes PGA pins that are integral to the PGA substrate without the use of solder. A process of making the coreless PGA substrate integrates the PGA pins by forming a build-up layer upon the PGA pins such that vias make direct contact to pin heads of the PGA pins.

Abstract: An electronic component package includes a substrate having a first surface, an electronic component mounted to the substrate, traces on the first surface, a terminal on the first surface, and a solder mask on the first surface. The solder mask includes a solder mask opening exposing the terminal. An electrically conductive coating and/or conductive coating feature is formed on the solder mask and extends into the solder mask opening to contact and be electrically connected to the terminal. The conductive coating may be grounded to shield the electronic component from electromagnetic interference (EMI). Further, the conductive coating provides a ground plane for the traces facilitating impedance matching of signals on the traces. In addition, the conductive coating has a high thermal conductivity thus enhancing heat dissipation from the electronic component.

Abstract: A semiconductor die has a first semiconductor die mounted to a carrier. A plurality of conductive pillars is formed over the carrier around the first die. An encapsulant is deposited over the first die and conductive pillars. A first stepped interconnect layer is formed over a first surface of the encapsulant and first die. The first stepped interconnect layer has a first opening. A second stepped interconnect layer is formed over the first stepped interconnect layer. The second stepped interconnect layer has a second opening. The carrier is removed. A build-up interconnect structure is formed over a second surface of the encapsulant and first die. A second semiconductor die over the first semiconductor die and partially within the first opening. A third semiconductor die is mounted over the second die and partially within the second opening. A fourth semiconductor die is mounted over the second stepped interconnect layer.

Abstract: A substrate comprising a plurality of layers, a first side and a second side; and a via extending through the substrate from the first side to the second side. The via comprises:a first substrate via extending through a first layer of the plurality of layers, the first substrate via having a first cross-sectional area; a first capture pad disposed under the first substrate via, wherein the first capture pad physically contacts the first substrate via; a second substrate via extending through a second layer of the plurality of layers, the second substrate via physically contacting the first capture pad, the second substrate via having a second cross-sectional area that is greater than the first cross-sectional area; and a second thermal and electrical contact pad disposed under the second dielectric layer, wherein the second contact pad physically contacts the second substrate via.

Abstract: A semiconductor construct includes a semiconductor substrate and connection pads provided on the semiconductor substrate. Some of the connection pads are connected to a common wiring and at least one of the remaining of the connection pads are connected to a wiring. The construct also includes a first columnar electrode provided to be connected to the common wiring and a second columnar electrode provided to be connected to a connection pad portion of the wiring.

Abstract: A wiring substrate includes an adhesive layer, a wiring layer, and a support substrate. The adhesive layer includes a first surface and a second surface that is opposite to the first surface. The wiring layer is formed on the first surface of the adhesive layer. The support substrate is formed on the second surface of the adhesive layer. The wiring layer is partially exposed in a through hole extending through the adhesive layer and the support substrate in a thicknesswise direction. The support substrate is adhered to the adhesive layer in a removable manner.

Abstract: A method for forming a semiconductor structure includes providing a semiconductor substrate and forming a dielectric layer over the semiconductor substrate. An opening is formed in the dielectric layer. A conductive line is formed in the opening, wherein the conductive line has an open void formed therein. A sealing metal layer is formed overlying the conductive line, the dielectric layer, and the open void, wherein the sealing metal layer substantially fills the open void. The sealing metal layer is planarized so that a top surface thereof is substantially level with a top surface of the conductive line. An interconnect feature is formed above the semiconductor substrate, wherein the interconnect feature is electrically coupled with the conductive line and the sealing metal layer-filled open void.

Abstract: Packaged microelectronic devices and methods for manufacturing packaged microelectronic devices are disclosed herein. In one embodiment, a packaged microelectronic device can include a support member, a first die attached to the support member, and a second die attached to the first die in a stacked configuration. The device can also include an attachment feature between the first and second dies. The attachment feature can be composed of a dielectric adhesive material. The attachment feature includes (a) a single, unitary structure covering at least approximately all of the back side of the second die, and (b) a plurality of interconnect structures electrically coupled to internal active features of both the first die and the second die.

Abstract: A semiconductor package includes a semiconductor wafer having a plurality of semiconductor die. A contact pad is formed over and electrically connected to an active surface of the semiconductor die. A gap is formed between the semiconductor die. An insulating material is deposited in the gap between the semiconductor die. An adhesive layer is formed over a surface of the semiconductor die and the insulating material. A via is formed in the insulating material and the adhesive layer. A conductive material is deposited in the via to form a through hole via (THV). A conductive layer is formed over the contact pad and the THV to electrically connect the contact pad and the THV. The plurality of semiconductor die is singulated. The insulating material can include an organic material. The active surface of the semiconductor die can include an optical device.

Abstract: Disclosed are a method for metallization during semiconductor wafer processing and the resulting structures. In this method, a passivation layer is patterned with first openings aligned above and extending vertically to metal structures below. A mask layer is formed and patterned with second openings aligned above the first openings, thereby forming two-tier openings extending vertically through the mask layer and passivation layer to the metal structures below. An electrodeposition process forms, in the two-tier openings, both under-bump pad(s) and additional metal feature(s), which are different from the under-bump pad(s) (e.g., a wirebond pad; a final vertical section of a crackstop structure; and/or a probe pad). Each under-bump pad and additional metal feature initially comprises copper with metal cap layers thereon.

Abstract: An integrated circuit structure includes a first conductive layer and an under bump metallization layer over the first conductive layer. The first conductive layer has a first conductive region and a second conductive region electrically isolated from the first conductive region. The under bump metallization layer has a first conductive area and a second conductive area electrically isolated from the first conductive area, the first conductive area substantially located over the first conductive region and the second conductive area substantially located over the second conductive region. At least one of the first conductive area or the first conductive region includes a first protrusion extending toward the second conductive area or second conductive region, respectively. Conductive vias connect the first conductive region to the second conductive area and connect the second conductive region to the first conductive area, and the vias include at least one via connected to the first protrusion.

Abstract: A first component includes a slice formed from an integrated circuit chip having a front face and a rear face. An encapsulation block encapsulates the integrated circuit chip such that front and rear faces of the chip and front and rear faces of the encapsulation block are co-planar to form front and rear faces of the slice. Front and rear electrical connection networks are provided on the front and rear faces, respectively, with the electrical connection networks linked by electrical connection vias passing through the encapsulation block. A thermal transfer layer at least partially covers the rear face. A second component may be behind and at a distance from the first component. Connection elements interposed between the first component and the second component include both thermal connection elements in contact with the thermal transfer layer and electrical connection elements interconnecting the first and second components.

Abstract: A device includes a substrate, and an alignment mark including a conductive through-substrate via (TSV) penetrating through the substrate.

Abstract: A method including introducing a dopant into a region of a substrate, etching a deep trench in the substrate through the region, gettering impurities introduced during etching of the deep trench using a pentavalent ion formed from a reaction between an element of the substrate and the dopant, wherein the charge of the pentavalent ion attracts the impurities, and filling the deep trench with a conductive material.

Abstract: There is provided a semiconductor device which includes a plurality of first through-substrate vias that are used to supply power from a first power supply and that penetrate through a substrate structure, and a plurality of second through-substrate vias that are used to supply power from a second power supply different from the first power supply and that penetrate through a substrate structure. The semiconductor device also includes a through-substrate via string composed by the first and second through-substrate vias, in which the first through-substrate vias are located adjacent to one another and the second through-substrate vias are also located adjacent to one another. The through-substrate via string is disposed in the substrate structure for extending in a first direction.

Abstract: A semiconductor device includes a semiconductor substrate configured to include a plurality of active regions that are stretched in parallel to each other, a plurality of first contact plugs and the plurality of active regions, wherein each active region is coupled with a corresponding first contact plug, and a contact pad configured to couple with a given number of first contact plugs among the plurality of first contact plugs. Misalignment occurring at the ends of a series of drain contacts may be prevented, and the size of well-pickup contacts may be decreased by forming contact plugs that are coupled with drain regions with the same distance to a well-pickup contact region without additionally forming well-pickup contact plugs and using the contact plugs as well-pickup contact plugs. Therefore, loss of a substrate may be minimized, and burden of Optical Proximity Correction (OPC) is relieved, reducing Turn-Around Time (TAT).

Abstract: A semiconductor device including a substrate and at least one alignment mark disposed on the substrate and having at least one hollow pattern. Therefore, the identification rate of the alignment mark can be high by the hollow pattern.

Abstract: An integrated circuit has a semiconductor die provided in a first IC layer and an inductor fabricated on a second IC layer. The inductor may have a winding and a magnetic core, which are oriented to conduct magnetic flux in a direction parallel to a surface of a semiconductor die. The semiconductor die may have active circuit components fabricated in a first layer of the die, provided under the inductor layer. The integrated circuit may include a flux conductor provided on a side of the die opposite the first layer. PCB connections to active elements on the semiconductor die may progress through the inductor layer as necessary.

Abstract: A chip arrangement may include: a first chip including a first contact, a second contact, and a redistribution structure electrically coupling the first contact to the second contact; a second chip including a contact; and a plurality of interconnects electrically coupled to the second contact of the first chip, wherein at least one interconnect of the plurality of interconnects electrically couples the second contact of the first chip to the contact of the second chip.

Abstract: A first through hole 16 and a second through hole 17 are formed which penetrate from a rear surface 10a side of an element formation surface 10b of a semiconductor substrate (silicon substrate 10) in which an element section Ra is formed, to the element formation surface. An outer circumference insulation film 12 is formed on the side wall of the bottom of the second through hole 17 to surround the outer circumference of the second through hole 17 having a larger opening diameter among these through holes.

Abstract: A stack of a first and second semiconductor structures is formed. Each semiconductor structure includes: a semiconductor bulk, an overlying insulating layer with metal interconnection levels, and a first surface including a conductive area. The first surfaces of semiconductor structures face each other. A first interconnection pillar extends from the first surface of the first semiconductor structure. A housing opens into the first surface of the second semiconductor structure. The housing is configured to receive the first interconnection pillar. A second interconnection pillar protrudes from a second surface of the second semiconductor structure which is opposite the first surface. The second interconnection pillar is in electric contact with the first interconnection pillar.

Abstract: A method of fabricating a semiconductor device includes forming a first insulation film over a semiconductor substrate, the semiconductor substrate including an outer region and an inner region located at an inner side of the outer region, forming a first wiring over the first insulation film in the inner region, forming a second insulation film over the first wiring and over the first insulation film, decreasing a film thickness of the second insulation film in the inner region with regard to a film thickness of the second insulation film in the outer region, and polishing the second insulation film after the decreasing of the film thickness of the second insulation film.

Abstract: A NAND flash memory device includes a plurality of continuous conductors disposed on a common level of a multilayer substrate, the plurality of continuous conductors including respective conductive lines extending in parallel along a first direction, respective contact pads disposed at ends of the respective conductive lines and respective conductive dummy lines extending in parallel from the contact pads along a second direction.

Abstract: An integrated circuit arrangement is disclosed having a wiring indentation and an auxiliary indentation in a dielectric layer. The wiring indentation contains a metal through which current flows during operation of the circuit arrangement. The auxiliary indentation contains a metal through which an electric current does not flow during operation of the circuit arrangement. The auxiliary indentation serves as an alignment mark during the production of the integrated circuit arrangement.

Abstract: In accordance with an embodiment, a structure comprises a substrate having a first area and a second area; a through substrate via (TSV) in the substrate penetrating the first area of the substrate; an isolation layer over the second area of the substrate, the isolation layer having a recess; and a conductive material in the recess of the isolation layer, the isolation layer being disposed between the conductive material and the substrate in the recess.

Abstract: A semiconductor apparatus including a semiconductor substrate having a first principal surface on which an electric circuit is formed and a second principal surface opposed to the first principal surface, and a through hole that penetrates the first principal surface and the second principal surface, a multilayered wiring layer having a plurality of conductive wiring layers connected to the electric circuit and a plurality of inter-layer insulating layers having an insulating layer opening of a same size and at a same position as a through hole opening which is an opening of the first principal surface of the through hole, an electrode pad that covers the insulating layer opening connected to the conductive wiring layer and a lead-out wiring layer having a through wiring layer connected to the electrode pad formed inside the through hole and a connection wiring layer formed integral with the through wiring layer.

Abstract: A semiconductor package and a manufacturing method thereof are provided. The semiconductor package includes a substrate, a semiconductor element, a package body and a conductive part. The substrate has an electrical contact. The semiconductor element is disposed on the substrate. The package body covers the semiconductor element and defines a through hole from which the electrical contact is exposed. Wherein, the package body includes a resin body and a plurality of fiber layers. The fiber layers are disposed in the resin body and define a plurality of fiber apertures which is arranged as an array. The conductive part is electrically connected to the substrate through the through hole.

Abstract: A chip assembly includes a PCB, a connecting pad fixed on the PCB, and a chip. The connecting pad defines a through hole. The chip is received in the through hole and fixed on the PCB by an adhesive distributed in the through hole. A thickness of the adhesive is less than that of the connecting pad.

Abstract: A manufacturing method of a semiconductor structure is disclosed. The manufacturing method includes the following steps: providing an underlying layer; forming a tri-layered photoresist on the underlying layer, which comprises forming a bottom photoresist layer on the underlying layer, forming a silicon-containing material layer on the bottom photoresist layer, and forming a patterned photoresist layer on the silicon-containing material layer; performing an atomic layer deposition (ALD) process for forming a thin layer on the tri-layered photoresist; and performing an etching process for forming a via hole, which comprises etching the silicon-containing material layer according to the thin layer on the tri-layered photoresist.

Abstract: A method of forming a semiconductor device includes forming a first conductive layer over the substrate. A dielectric layer, having a first opening, is formed over the first conductive layer. A seed layer is deposited over the first dielectric layer and in the first opening. A layer is formed of conductive nanotubes from the seed layer over the first dielectric layer and over the first opening. A second dielectric is formed over the layer of conductive nanotubes. An opening is formed in the second dielectric layer over the first opening. Conductive material is deposited in the second opening.

Abstract: A method includes providing a semiconductor chip having a first main surface and a second main surface opposite to the first main surface. An electrically insulating material is deposited on the first main surface of the semiconductor chip using a plasma deposition method. A first electrically conductive material is deposited on the second main surface of the semiconductor chip using a plasma deposition method.

Abstract: Disclosed is a light emitting device package. The light emitting device package includes a substrate including a recess, a light emitting chip on the substrate and a first conductive layer electrically connected to the light emitting chip. And the first conductive layer includes at least one metal layer electrically connected to the light emitting chip on an outer circumference of the substrate.

Abstract: An apparatus including a bypass structure for complementary metal-oxide-semiconductor (CMOS) and/or microelectromechanical system (MEMS) devices, and method for fabricating such apparatus, is disclosed. An exemplary apparatus includes a first substrate; a second substrate that includes a MEMS device; an insulator disposed between the first substrate and the second substrate; and an electrical bypass structure disposed in the insulator layer that contacts a portion of the first substrate, wherein the electrical bypass structure is electrically isolated from the MEMS device in the second substrate and any device included in the first substrate.

Abstract: An electronic component device includes a substrate, an electrode post made of a metal material, provide to stand on the substrate, and an electronic component whose connection electrode is connected to the electrode post, wherein the connection electrode of the electronic component and the electrode post are joined by an alloy layer including a metal which is different from the metal material of the electrode post.

Abstract: An extended landing pad substrate package includes a dielectric layer having an upper surface and an opposite lower surface. A lower circuit pattern is embedded in the lower surface of the dielectric layer. The lower circuit pattern includes traces having a first thickness and extended landing pads having a second thickness greater than the first thickness. Blind via apertures are formed through an upper circuit pattern embedded into the upper surface of the dielectric layer, through the dielectric layer and to the extended landing pads. The length of the blind via apertures is minimized due to the increase second thickness of the extended landing pads as compared to the first thickness of traces. Accordingly, the width of the blind via apertures at the upper surface of the dielectric layer is minimized.

Abstract: A device includes a polymer, a device die in the polymer, and a plurality of Through Assembly Vias (TAVs) extending from a top surface to a bottom surface of the polymer. A bulk metal feature is located in the polymer and having a top-view size greater than a top-view size of each of the plurality of TAVs. The bulk metal feature is electrically floating. The polymer, the device die, the plurality of TAVs, and the bulk metal feature are portions of a package.

Abstract: Systems, methods, and devices are provided to enable an integrated circuit device of relatively higher capacity. Such an integrated circuit device may include at least two component integrated circuits that communicate with one another. Specifically, the component integrated circuits may communicate through a “stitched silicon interposer” that is larger than a reticle limit of the lithography system used to manufacture the interposer. To achieve this larger size, the stitched silicon interposer may be composed of at least two component interposers, each sized within the reticle limit and each separated from one another by a die seal structure.

Abstract: A device includes a first semiconductor chip with a first contact pad on a first face and a second semiconductor chip with a first contact pad on a first face. The second semiconductor chip is placed over the first semiconductor chip, wherein the first face of the first semiconductor chip faces the first face of the second semiconductor chip. Exactly one layer of an electrically conductive material is arranged between the first semiconductor chip and the second semiconductor chip. The exactly one layer of an electrically conductive material electrically couples the first contact pad of the first semiconductor chip to the first contact pad of the second semiconductor chip.

Abstract: A microstrip MMIC chip flip-chip mounted to a printed circuit board with conductive vias passing through the chip to electrical connect a ground plane of the microstrip MMIC chip to a ground conductor of the printed circuit board.