Abstract: Embodiments of the present description include stacked microelectronic dice embedded in a microelectronic substrate and methods of fabricating the same. In one embodiment, at least one first microelectronic die is attached to a second microelectronic die, wherein an underfill material is provided between the second microelectronic die and the at least one first microelectronic die. The microelectronic substrate is then formed by laminating the first microelectronic die and the second microelectronic die in a substrate material.

Abstract: A semiconductor device includes a stacked plurality of memory chips. The memory chips each include a plurality of memory banks, a plurality of read/write buses that are assigned to the respective memory banks, and a plurality of penetration electrodes that are assigned to the respective read/write buses and arranged through the memory chip. Penetration electrodes arranged in the same positions as seen in a stacking direction are connected in common between the chips. In response to an access request, the memory chips activate the memory banks that are arranged in respective different positions as seen in the stacking direction, whereby data is simultaneously input/output via the penetration electrodes that lie in different planar positions.

Abstract: The present invention provides a semiconductor wafer, semiconductor package and semiconductor process. The semiconductor wafer includes a substrate, at least one metal segment and a plurality of dielectric layers. The semiconductor wafer is defined as a plurality of die areas and a plurality of trench areas, each of the die areas has an integrated circuit including a plurality of patterned metal layers disposed between the dielectric layers. The trench areas are disposed between the die areas, and the at least one metal segment is disposed in the trench area and insulated from the integrated circuit of the die area.

Abstract: The invention provides a radio-frequency (RF) device package and a method for fabricating the same. An exemplary embodiment of a radio-frequency (RF) device package includes a base, wherein a radio-frequency (RF) device chip is mounted on the base. The RF device chip includes a semiconductor substrate having a front side and a back side. A radio-frequency (RF) component is disposed on the front side of the semiconductor substrate. An interconnect structure is disposed on the RF component, wherein the interconnect structure is electrically connected to the RF component, and a thickness of the semiconductor substrate is less than that of the interconnect structure. A through hole is formed through the semiconductor substrate from the back side of the semiconductor substrate, and is connected to the interconnect structure. A TSV structure is disposed in the through hole.

Abstract: An integrated circuit device including an interlayer insulating layer on a substrate, a wire layer on the interlayer insulating layer, and a through-silicon-via (TSV) contact pattern having an end contacting the wire layer and integrally extending from inside of a via hole formed through the interlayer insulating layer and the substrate to outside of the via hole.

Abstract: Method and apparatus for programmable heterogeneous integration of stacked semiconductor die are described. In some examples, a semiconductor device includes a first integrated circuit (IC) die including through-die vias (TDVs); a second IC die vertically stacked with the first IC die, the second IC die including inter-die contacts electrically coupled to the TDVs; the first IC die including heterogeneous power supplies and a mask-programmable interconnect, the mask-programmable interconnect mask-programmed to electrically couple a plurality of the heterogeneous power supplies to the TDVs; and the second IC die including active circuitry, coupled to the inter-die contacts, configured to operate using the plurality of heterogeneous power supplies provided by the TDVs.

Abstract: An apparatus includes a first die having a first bus, a second die having a second bus stacked on the first die, a plurality of through silicon vias connecting the first bus to the second bus, and first control logic for sending data to identified ones of the plurality of through silicon vias. Also, optionally, second control logic for determining a first set of the plurality of through silicon vias that are nonfunctional, wherein the second control logic is configured to send information to the first control logic identifying the first set of the plurality of through silicon vias or identifying a second set of through silicon vias that are functional. Also a method of sending signals through a plurality of through silicon vias.

Abstract: A semiconductor having through-silicon via includes a substrate, an outer dielectric liner, an inner dielectric liner and a conductive contacting layer. The substrate has a top surface and a bottom surface and defining at least one through-silicon via going through the top surface toward the bottom surface. The outer dielectric liner covers the top surface of the substrate. The inner dielectric liner covers a wall of the through-silicon via. The thickness of the inner dielectric liner reduces from the top surface toward the bottom surface. The conductive contacting liner over fills the through-silicon via and is exposed on the top surface.

Abstract: An electronic device can include a substrate including a first region having a first thickness, and a second region having a second thickness different from the first thickness. The electronic device can include a via within the first region. The electronic device can include a conductive structure adjacent to the first region and connected to the via, wherein a combined thickness of the first thickness and a thickness of the conductive structure is thicker than the second thickness. In another embodiment, an interposer may have a similar structure, with laterally offset conductive structures that allow for lateral routing of electronic signals. A process of forming an electronic device can include forming a via and removing a portion of the substrate. The process can include forming a conductive structure connected to the via, wherein the conductive structure is adjacent to a region where the portion of the substrate has been removed.

Abstract: Semiconductor structures are fabricated that include a semiconductor material bonded to a substrate with a layer of dielectric material between the semiconductor material and the substrate. At least one fluidic microchannel extends in a lateral direction through the layer of dielectric material between the semiconductor material and the substrate. The at least one fluidic microchannel includes at least one laterally extending section having a transverse cross-sectional shape entirely surrounded by the layer of dielectric material.

Abstract: In a semiconductor device, the thickness of an insulating film formed in a through hole is reduced, while an annular groove having an insulating material embedded therein is provided so as to ensure a sufficient total thickness of the insulator, whereby a through silicon via is provided with an insulating ring which is improved in both processability and functionality.

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: Semiconductor devices with air gaps around the through-silicon via are formed. Embodiments include forming a first cavity in a substrate, filling the first cavity with a sacrificial material, forming a second cavity in the substrate, through the sacrificial material, by removing a portion of the sacrificial material and a portion of the substrate below the sacrificial material, filling the second cavity with a conductive material, removing a remaining portion of the sacrificial material to form an air gap between the conductive material and the substrate, and forming a cap over the air gap.

Abstract: A chip package is described. This chip package includes a substrate having a side at an angle relative to the top and bottom surfaces of the substrate that is between that of a direction parallel to the top and bottom surfaces and that of a direction perpendicular to the top and bottom surfaces (i.e., between 0° and 90°). This side may be configured to couple to a stack of semiconductor dies in which the semiconductor dies are offset from each other in a direction parallel to the top and bottom surfaces so that one side of the stack defines a stepped terrace. For example, the side may include electrical pads. These electrical pads may be coupled to electrical pads on the top surface by through-substrate vias (TSVs) in the substrate. Moreover, the electrical pads on the top surface may be configured to couple to an integrated circuit.

Abstract: A semiconductor wafer has an integrated through substrate via (TSV). The semiconductor wafer includes a substrate. A dielectric layer may be formed on a first side of the substrate. A through substrate via may extend through the dielectric layer and the substrate. The through substrate via may include a conductive material and an isolation layer. The isolation layer may at least partially surround the conductive material. The isolation layer may have a tapered portion.

Abstract: A method for manufacturing a contact plug is provided. The method includes providing a silicon substrate having at least one opening. A titanium layer is conformably formed in the opening. A first barrier layer is conformably formed on the titanium layer in the opening. A rapid thermal process is performed on the titanium layer and the first barrier layer. After performing the rapid thermal process, a second barrier layer is conformably formed on the first barrier layer in the opening.

Abstract: Provided is a substrate, including a substrate material, two conductive structures, and at least one diode. The two conductive structures extend from a first surface of the substrate material to a second surface of the substrate material via two through holes penetrating through the substrate material. The at least one diode is embedded in the substrate material at a sidewall of one of the through holes.

Abstract: A method for forming a device is disclosed. A substrate having first and second major surfaces is provided. A stress buffer is formed in the substrate. A through silicon via (TSV) contact is formed between the stress buffer. The stress buffer has a depth less than a depth of the TSV contact. The stress buffer alleviates stress created by the difference in coefficient thermal expansion (CTE) between the TSV contact and the substrate.

Abstract: A metal trench de-noise structure includes a trench disposed in a substrate, an insulating layer deposited on the sidewall of the trench, an Inter-Layer Dielectric layer covering the substrate and the insulating layer, and a metal layer penetrating the Inter-Layer Dielectric layer to fill up the trench. The metal layer may be grounded or floating.

Abstract: Provided is a three-dimensional semiconductor device and method for fabricating the same. The device includes a first electrode structure and a second electrode structure stacked sequentially on a substrate. The first and second electrode structures include stacked first electrodes and stacked second electrodes, respectively. Each of the first and second electrodes includes a horizontal portion parallel with the substrate and an extension portion extending from the horizontal portion along a direction penetrating an upper surface of the substrate. Here, the substrate may be closer to top surfaces of the extension portions of the first electrodes than to the horizontal portion of at least one of the second electrodes.

Abstract: A structure including a substrate having a backside, a first through silicon via having sides, a bottom surface, and a first height protruding from the backside of the substrate, and a first conductor facing the backside of the substrate and in electrical contact with the first through silicon via. The structure further including a second through silicon via having sides, a bottom surface, and a second height protruding from the backside of the substrate, wherein the second height is less than the first height, and a second conductor facing the backside of the substrate and in electrical contact with the second through silicon via, where a first via liner contacts the sides and the bottom surface of the first through silicon via and contacts the bottom surface but not the sides of the second through silicon via.

Abstract: A semiconductor device is provided, including a semiconductor substrate that includes a semiconductor; an electrode layer formed above a first surface side inside the semiconductor substrate; a conductor layer formed above the electrode layer and above the first surface of the semiconductor substrate; a hole formed through the semiconductor substrate from a second surface of the semiconductor substrate to the conductor layer; and a wiring layer that is electrically connected to the electrode layer via the conductor layer at an end portion of the vertical hole, and that extends to the second surface of the semiconductor substrate, the wiring layer being physically separated from the electrode layer by an insulating layer disposed therebetween.

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: An embodiment of a die comprising: a semiconductor body including a front side, a back side, and a lateral surface; an electronic device, formed in said semiconductor body and including an active area facing the front side; a vertical conductive connection, extending through the semiconductor body and defining a conductive path between the front side and the back side of the semiconductor body; and a conductive contact, defining a conductive path on the front side of the semiconductor body, between the active area and the vertical conductive connection, wherein the vertical conductive connection is formed on the lateral surface of the die, outside the active area.

Abstract: A semiconductor device includes a semiconductor substrate having opposed main and back surfaces; first and second electrodes in a device region of the substrate, and spaced apart from each other; a metal film on the main surface and joined to the second electrode; an air gap between part of the main surface and the metal film, enveloping the first electrode, and having an opening; a cured resin closing the opening; a liquid repellent film increasing contact angle of the resin, relative to contact angles on the substrate and the metal film; a first metal film joined to the metal film, covering the metal film and the cured resin, and joined to an outer peripheral region of the substrate, at a periphery of the device region; and a second metal film on the back surface and connected to the first electrode through a via hole penetrating the substrate.

Abstract: A method of providing a via hole and routing structure includes: providing a substrate wafer having recesses and blind holes provided in the surface of the wafer; providing an insulating layer in the recesses and holes; metallizing the holes and recesses; and removing the oxide layer in the bottom of the holes to provide contact between the back side and the front side of the wafer. A semiconductor device, including a substrate having at least one metallized via extending through the substrate and at least one metallized recess forming a routing together with the via. There is an oxide layer on the front side field and on the back side field. The metal in the recess and the via is flush with the oxide on the field on at least the front side, whereby a flat front side is provided. The thickness of the semiconductor device is <300 ?m.

Abstract: A first substrate with a penetration electrode formed thereon is stacked on a second substrate with a protruding electrode formed thereon. The penetration electrode has a recessed portion. The substrates are stacked with the protruding electrode entered in the recessed portion. A distal width of the protruding electrode is smaller than an opening width of the recessed portion.

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: Embodiments of the present invention provide a novel process integration for air gap formation at the sidewalls for a Through Silicon Via (TSV) structure. The sidewall air gap formation scheme for the TSV structure of disclosed embodiments reduces parasitic capacitance and depletion regions in between the substrate silicon and TSV conductor, and serves to also reduce mechanical stress in silicon substrate surrounding the TSV conductor.

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: 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: Provided is a power voltage supply apparatus of a 3-dimensional (3D) semiconductor. The power voltage supply apparatus includes a plurality of integrated circuits (ICs) which each include a first through silicon via (TSV) and a second TSV, are stacked such that the first TSVs are connected and second TSVs are connected, and are mounted on a printed circuit board (PCB), wherein a first PCB line formed on the PCB and supplying a first voltage is connected to a bottom of a first TSV of a bottom IC from among the plurality of ICs, and a second PCB line formed on the PCB and supplying a second voltage is connected to a top of a second TSV of a top IC.

Abstract: There is formed a first concave portion that extends inside a semiconductor substrate from a main surface thereof. An insulating film is formed over the main surface, over a side wall and a bottom wall of the first concave portion so as to cover an element and to form a capped hollow in the first concave portion. A first hole portion is formed in the insulating film so as to reach the hollow in the first concave portion from an upper surface of the insulating film, and to reach the semiconductor substrate on the bottom wall of the first concave portion while leaving the insulating film over the side wall of the first concave portion. There is formed a second hole portion that reaches the conductive portion from the upper surface of the insulating film. The first and second hole portions are formed by the same etching treatment.

Abstract: A through silicon via structure is disclosed. The through silicon via includes: a substrate; a first dielectric layer disposed on the substrate and having a plurality of first openings, in which a bottom of the plurality of first openings is located lower than an original surface of the substrate; a via hole disposed through the first dielectric layer and the substrate, in which the via hole not overlapping for all of the plurality of first openings; a second dielectric layer disposed within the plurality of first openings and on a sidewall of the via hole while filling the plurality of first openings; and a conductive material layer disposed within the via hole having the second dielectric layer on the sidewall of the via hole, thereby forming a through silicon via.

Abstract: A semiconductor device comprises a substrate, a through-silicon via (TSV) penetrating the substrate, a plurality of first interconnect structures, right above the TSV, configured for electrically coupling the TSV to a higher-level interconnect, a second interconnect structure traversing the TSV from the top and being configured for interconnect routing of an active device and a plurality of dummy metal patterns, right above the TSV, electrically isolated from the TSV, the first interconnect structures and the second interconnect structure.

Abstract: An integrated circuit is provided with a substrate, an electrode, two diffusion areas, and a resistance heater. The substrate includes a first surface and second surface that are substantially parallel to each other. The electrode is laminated onto the first surface. The two diffusion areas are disposed within the substrate in the vicinity of the electrode to form one transistor with the electrode. The resistance heater is located on an area of the second surface across the substrate from the electrode. The resistance heater produces heat by allowing electric current to flow.

Abstract: Disclosed herein is a device including a substrate and first and second chips stacked on the substrate. The first and second chips have penetration electrodes that are penetrating therethrough. Power terminals of the first and second chips are connected to each other and arranged in a first arrangement pitch. Signal terminals of the first and second chips are connected to each other and arranged in a second arrangement pitch that is smaller than the first arrangement pitch.

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 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: An integrated circuit that detects whether a through silicon via has defects or not, at a wafer level. The integrated circuit includes a semiconductor substrate, a through silicon via configured to be formed in the semiconductor substrate to extend to a certain depth from the surface of the semiconductor substrate, an output pad, and a current path providing unit configured to provide a current, flowing between the semiconductor substrate and the through silicon via, to the output pad during a test mode.

Abstract: A method and structure for stabilizing an array of micro devices is disclosed. The array of micro devices is formed on an array of stabilization posts formed from a thermoset material. Each micro device includes a bottom surface that is wider than a corresponding stabilization post directly underneath the bottom surface.

Abstract: The inventive concept provides semiconductor devices having through-vias and methods for fabricating the same. The method may include forming a via-hole opened toward a top surface of a substrate and partially penetrating the substrate, forming a via-insulating layer having a first thickness on a bottom surface of the via-hole and a second thickness smaller than the first thickness on an inner sidewall of the via-hole, forming a through-via in the via-hole which the via-insulating layer is formed in, and recessing a bottom surface of the substrate to expose the through-via. Forming the via-insulating layer may include forming a flowable layer on the substrate, and converting the flowable layer into a first flowable chemical vapor deposition layer having the first thickness on the bottom surface of the via-hole.

Abstract: A semiconductor device includes a semiconductor substrate having a first side and a second side opposite the first side, an active area and a through contact area, the active area including a transistor structure having a control electrode, the through contact area including a semiconductor mesa having insulated sidewalls. The semiconductor device further includes a first metallization on the first side in the active area and a recess extending from the first side into the semiconductor substrate and between the active area and the through contact area and including in the through contact area a horizontally widening portion, the recess being at least partly filled with a conductive material forming a first conductive region in ohmic contact with the semiconductor mesa and the transistor structure. The semiconductor device also includes a control metallization on the second side and in ohmic contact with the semiconductor mesa.

Abstract: A semiconductor package comprises a substrate having a first opening formed therethrough, a first semiconductor chip stacked on the substrate in a flip chip manner and having a second opening formed therethrough, a second semiconductor chip stacked on the first semiconductor chip in a flip chip manner and having a third opening formed therethrough, and a molding material covering the first semiconductor chip and the second semiconductor chip and filling up a space between the substrate and the first semiconductor chip, a space between the first semiconductor chip and the second semiconductor chip, and filling each of the first opening, the second opening, and the third opening.

Abstract: A compound semiconductor device includes a substrate having an opening formed from the rear side thereof; a compound semiconductor layer disposed over the surface of the substrate; a local p-type region in the compound semiconductor layer, partially exposed at the end of the substrate opening; and a rear electrode made of a conductive material, disposed in the substrate opening so as to be connected to the local p-type region.

Abstract: A semiconductor device has an interconnect structure with a cavity formed partially through the interconnect structure. A first semiconductor die is mounted in the cavity. A first TSV is formed through the first semiconductor die. An adhesive layer is deposited over the interconnect structure and first semiconductor die. A shielding layer is mounted over the first semiconductor die. The shielding layer is secured to the first semiconductor die with the adhesive layer and grounded through the first TSV and interconnect structure to block electromagnetic interference. A second semiconductor die is mounted to the shielding layer and electrically connected to the interconnect structure. A second TSV is formed through the second semiconductor die. An encapsulant is deposited over the shielding layer, second semiconductor die, and interconnect structure. A slot is formed through the shielding layer for the encapsulant to flow into the cavity and cover the first semiconductor die.

Abstract: A semiconductor device includes: an active region located in an upper portion of a semiconductor substrate; a through-hole electrode penetrating the substrate, and made of a conductor having a thermal expansion coefficient larger than that of a material for the substrate; and a stress buffer region located in the upper portion of the substrate and sandwiched between the through-hole electrode and the active region. The stress buffer region does not penetrate the substrate and includes a stress buffer part made of a material having a thermal expansion coefficient larger than that of the material for the substrate and an untreated region where the stress buffer part is not present. The stress buffer part is located in at least two locations sandwiching the untreated region in a cross section perpendicular to a surface of the substrate and passing through the through-hole electrode and the active region.

Abstract: A three dimensional integrated circuit (3D-IC) structure, method of manufacturing the same and design structure thereof are provided. The 3D-IC structure includes two chips having a dielectric layer, through substrate vias (TSVs) and pads formed on the dielectric layer. The dielectric layer is formed on a bottom surface of each chip. Pads are electrically connected to the corresponding TSVs. The chips are disposed vertically adjacent to each other. The bottom surface of a second chip faces the bottom surface of a first chip. The pads of the first chip are electrically connected to the pads of the second chip through a plurality of conductive bumps. The 3D-IC structure further includes a thermal via structure vertically disposed between the first chip and the second chip and laterally disposed between the corresponding conductive bumps. The thermal via structure has an upper portion and a lower portion.

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: On a wiring conversion part connected to a first conductive film and a second conductive film each functioning as a wiring, a hollow portion is formed inside the second conductive film. A first transparent conductive film provided on the second conductive film is formed so as to cover an upper surface of the second conductive film and an end surface thereof exposed on the hollow portion, and so as not to cover an outer peripheral end surface of the second conductive film. A second transparent conductive film which is a layer above the first transparent conductive film is connected to the second conductive film and the first conductive film, so that the first conductive film and the second conductive film are electrically connected.