Abstract: A modularized interposer includes a plurality of interposer units that are assembled to provide a complete set of electrical connections between two semiconductor chips. At least some of the plurality of interposer units can be replaced with other interposer units having an alternate configuration to enable selection of different functional parts of semiconductor chips to be connected through the modularized interposer. Bonding structures, connected to conductive metal pads located at peripheries of neighboring interposer units and an overlying or underlying portion of a semiconductor chip, can provide electrical connections between the neighboring interposer units. The interposer units can be provided by forming through-substrate vias (TSV's) in a substrate, forming patterned conductive structures on the substrate, and cutting the substrate into interposers.

Abstract: A wiring substrate includes a block with substrates laid out in an array. The block includes corners and a plan view center. Each substrate includes a substrate body. Pads are formed on the substrate body. Each pad includes a pad surface. The pads of the substrates include first pads, which are the pads of one of the substrates located in at least one of the corners of the block. The pad surface of each of the first pads includes a first axis extending from the first pad toward the plan view center of the block. The pad surface of each of the first pads has a first length along the corresponding first axis and a second length along a second axis, which is orthogonal to the first axis. The first length is longer than the second length.

Abstract: Semiconductor chips are described that combine a semiconductor device and a capacitor onto a single substrate such that the semiconductor device and the capacitor are electrically isolated from each other. In one example, a semiconductor chip includes a substrate having a first side and a second side, wherein the second side is opposite the first side. The semiconductor chip further includes a semiconductor device formed on the first side of the substrate and an electrically insulating layer formed on at least a portion of the second side of the substrate. The semiconductor chip further includes a capacitor device formed on at least a portion of the electrically insulating layer on the second side of the substrate, wherein the capacitor device is electrically insulated from the semiconductor device.

Abstract: A method for forming a semiconductor structure including providing a substrate; forming a dielectric layer covering a surface of the substrate; forming a plurality of first through holes exposing the surface of the substrate by etching the dielectric layer; forming first conductive vias by filling the plurality of first through holes using a first metal material and first conductive lines on the first conductive vias also using the first metal material; forming a plurality of second through holes exposing the surface of the substrate by etching the dielectric layer; and forming second conductive vias by filling the plurality of second through holes using a second metal material, different from the first metal material, and second conductive lines over the second conductive vias also using the second metal material, wherein the second metal material has a different anti-electromigration ability from the first metal material.

Abstract: A method of forming an integrated circuit includes forming at least one transistor over a substrate. Forming the at least one transistor includes forming a gate dielectric structure over a substrate. A work-function metallic layer is formed over the gate dielectric structure. A conductive layer is formed over the work-function metallic layer. A source/drain (S/D) region is formed adjacent to each sidewall of the gate dielectric structure. At least one electrical fuse is formed over the substrate. Forming the at least one electrical fuse includes forming a first semiconductor layer over the substrate. A first silicide layer is formed on the first semiconductor layer.

Abstract: A methodology enabling filling of high aspect ratio cavities, with no voids or gaps, in an IC device and the resulting device are disclosed. Embodiments include providing active area and/or gate contacts in a first ILD; forming selective protective caps on upper surfaces of the contacts; forming a second ILD on upper surfaces of the protective caps and on an upper surface of the first ILD; forming a hard-mask stack on the second ILD; forming, in the second ILD and hard-mask stack, cavities exposing one or more protective caps; removing selective layers in the stack to decrease depths of the cavities; and filling the cavities with a metal layer, wherein the metal layer in one or more cavities connects to an upper surface of the one or more exposed protective caps.

Abstract: A power semiconductor module may include a first device and a second device spaced apart from the first device at a predetermined interval. A first assembling terminal is fixedly disposed between the first device and the second device to be a first connection terminal. A second assembling terminal is fixedly assembled to contact outer surfaces of the first device and the second device to be a second connection terminal.

Abstract: Semiconductor devices are provided. A semiconductor device includes gaps between conductive patterns. Moreover, the semiconductor device includes a permeable layer on the conductive patterns. Methods of fabricating semiconductor devices are also provided.

Abstract: A semiconductor device includes a first die having top, bottom, and peripheral surfaces. A bond pad is formed over the top surface. An organic material is connected to the first die and disposed around the peripheral surface. A via hole is formed in the organic material. A metal trace connects the via hole to the bond pad. A conductive material is deposited in the via hole. A redistribution layer (RDL) has an interconnection pad disposed over the top surface of the first die.

Abstract: Provided is an alignment mark having a plurality of sub-resolution elements. The sub-resolution elements each have a dimension that is less than a minimum resolution that can be detected by an alignment signal used in an alignment process. Also provided is a semiconductor wafer having first, second, and third patterns formed thereon. The first and second patterns extend in a first direction, and the third pattern extend in a second direction perpendicular to the first direction. The second pattern is separated from the first pattern by a first distance measured in the second direction. The third pattern is separated from the first pattern by a second distance measured in the first direction. The third pattern is separated from the second pattern by a third distance measured in the first direction. The first distance is approximately equal to the third distance. The second distance is less than twice the first distance.

Abstract: According to various embodiments, a method for manufacturing a semiconductor device may include providing a semiconductor workpiece including a device region at a first side of the semiconductor workpiece, wherein a mechanical stability of the semiconductor workpiece is insufficient to resist at least one back end process without damage, and depositing at least one conductive layer over a second side of the semiconductor workpiece opposite the first side of the semiconductor workpiece, wherein the at least one conductive layer increases the mechanical stability of the semiconductor workpiece to be sufficient to resist the at least one back end process without damage.

Abstract: In various embodiments, a power semiconductor housing having an integrated circuit is provided. The integrated circuit may include: a first gate pad and a second gate pad; and a first gate contact and a second gate contact; wherein the first gate pad is electrically connected to the first gate contact; wherein the second gate pad is electrically connected to the second gate contact. The integrated circuit may further include a drain-contact surface, wherein the drain-contact surface is connected to a drain contact; and a second drain contact, which is electrically connected to the drain-contact surface of the integrated circuit.

Abstract: A method includes mounting a wafer-level package substrate over a carrier, and pre-cutting the wafer-level package substrate to form trenches extending from a top surface of the wafer-level package substrate into the wafer-level package substrate. A plurality of dies is bonded over the wafer-level package substrate. The plurality of dies is molded in a molding material to form a wafer-level package, with the wafer-level package including the wafer-level package substrate, the plurality of dies, and the molding material. The carrier is detached from the wafer-level package. The wafer-level package is sawed into a plurality of packages, with each of the plurality of packages including a portion of the wafer-level package substrate and one of the plurality of dies.

Abstract: A method of forming a semiconductor package includes providing a substrate having one or more conductive elements disposed therein. Each conductive element extends from a first surface of the substrate toward a second surface of the substrate extending beyond the second surface. The second surface comprises one or more substrate regions not occupied by a conductive element. A first die is attached within a substrate region, and the first die is coupled to at least one of the conductive elements. The first die may be coupled to at least one of the conductive elements by a wire bond connection. Alternatively, an RDL is formed over the second surface, and the first die is coupled to at least one conductive element through the RDL. A second die may be attached to an outer surface of the RDL, and the second die is electrically coupled to the first die through the RDL.

Abstract: A package structure is disclosed, which includes a substrate having a body, a plurality of conductive pads formed on the body and a surface passivation layer formed on the body and having a plurality of openings for exposing the conductive pads; a plurality of conductive vias formed in the openings of the surface passivation layer and electrically connected to the conductive pads; a plurality of circuits formed on the surface passivation layer and electrically connected to the conductive vias, wherein the circuits have a plurality of electrical contacts; at least a pattern portion formed on the surface passivation layer and intersecting with the circuits; and a second passivation layer formed on the surface passivation layer, the circuits and the pattern portion d having a plurality of openings for exposing portions of the electrical contacts of the circuits, thereby strengthening the bonding between the circuits and the passivation layers.

Abstract: An L-shaped sidewall protection process is used for Cu pillar bump technology. The L-shaped sidewall protection structure is formed of at least one of non-metal material layers, for example a dielectric material layer, a polymer material layer or combinations thereof.

Abstract: An electronic device includes a surface-mounted component and a mounting component on which the surface-mounted component is mounted, the surface-mounted component includes a first bump and a second bump, a cross-sectional area of which in an in-plane direction of a surface facing the mounting component is larger than that of the first bump, on the surface facing the mounting component, the mounting component includes a first pad that is soldered to the first bump and a second pad soldered to the second bump on the surface facing the surface-mounted component, and a ratio of an area of the second pad to the cross-sectional area of the second bump is larger than a ratio of an area of the first pad to the cross-sectional area of the first bump.

Abstract: A microelectronic interconnect element can include a plurality of first metal lines and a plurality of second metal lines interleaved with the first metal lines. Each of the first and second metal lines has a surface extending within the same reference plane. The first metal lines have surfaces above the reference plane and remote therefrom and the second metal lines have surfaces below the reference plane and remote therefrom. A dielectric layer can separate a metal line of the first metal lines from an adjacent metal line of the second metal lines.

Abstract: A package structure, comprising: a substrate, having at least one conductive units provided at a first surface of the substrate; at least one first die, provided on a second surface of the substrate; a connecting layer; a second die, provided on the connecting layer, wherein the connecting layer comprises at least one bump for connecting the first die to the second die such that the first die and the second die are electrically connected; and at least one bonding wire, for electrically connecting the first die to the conductive units or the substrate.

Abstract: A semiconductor device includes a semiconductor chip provided with a plurality of bumps arranged in a peripheral alignment, a substrate provided with a plurality of electrodes, and an insulating resin adhesive film. The semiconductor chip is affixed to the substrate via the insulating resin adhesive film such that the electrodes are in positions corresponding to the positions of the bumps. The insulating resin adhesive film has a minimum melt viscosity of 8×103 to 1×105 Pa·s, covers 70 to 90% the area of the region enclosed with the plurality of bumps, and heat cured. The bumps and the electrodes corresponding thereto are arranged so that they are opposed to each other and establish metallic contact therebetween. A periphery of the insulating resin adhesive film is defined between the plurality of bumps and the outer edge of the semiconductor chip, exclusive.

Abstract: A method for fabricating a stacked microelectronic device includes attaching a first package layer to a second package layer to form stacked microelectronic layers. Saw streets of the first package layer overlie and are aligned with saw streets of the second package layer. The first and second package layers include respective edge connectors formed between the saw streets and electronic components in the first and second package layers. A through package via is formed in one of the saw streets of the first and second package layers. The via is filled with conductive material. The stacked package layers are singulated along the saw streets in a manner that retains a portion of the conductive material to form a sidewall connector between at least two of the edge connectors.

Abstract: A semiconductor assembly includes a frame having at least one opening, an identical number of electrically conductive first contact plates, and an identical number of chip arrays. Each chip array has a number of semiconductor chips that are cohesively connected to one another by an embedding compound. In addition, each of the semiconductor chips has a first load terminal and a second load terminal arranged at mutually opposite sides of the relevant semiconductor chip. One of the chip arrays is inserted into each of the openings. Each of the first contact plates is arranged above one of the chip arrays in such a way that, for each of the semiconductor chips, the first load terminal is situated at a side of said semiconductor chip facing the first contact plate and the second load terminal is situated a of said semiconductor chip facing away from the first contact plate.

Abstract: A semiconductor system may include first semiconductor device including a first pad, a second pad and a first test input pad, and suitable for storing data inputted in series through the first test input pad and outputting the stored data in parallel through the first pad and the second pad; a second semiconductor device including a third pad, a fourth pad and a second test output pad, and suitable for storing data inputted in parallel through the third pad and the fourth pad, a first through via connecting the first pad and the third pad so that the stored data outputted in parallel through the first pad is inputted in parallel through the third pad; and a second through via connecting the second pad and the fourth pad so that the stored data outputted in parallel through the second pad is inputted in parallel through the fourth pad.

Abstract: In a conventional electronic device and a method of manufacturing the same, reduction in cost of the electronic device is hindered because resin used in an interconnect layer on the solder ball side is limited. The electronic device includes an interconnect layer (a first interconnect layer) and an interconnect layer (a second interconnect layer). The second interconnect layer is formed on the undersurface of the first interconnect layer. The second interconnect layer is larger in area seen from the top than the first interconnect layer and is extended to the outside from the first interconnect layer.

Abstract: An LED-based light source for generating light having a selected dominant wavelength ?ds comprises a package housing a plurality of LEDs consisting of LEDs from first and second wavelength bins. The first wavelength bin comprises LEDs having a dominant wavelength ?d1 that is within a first wavelength range and the second wavelength bin comprises LEDs having a dominant wavelength ?d2 that is within a second wavelength range. The first wavelength bin can comprise LEDs having a dominant wavelength that is shorter than the selected dominant wavelength while the second wavelength bin comprises LEDs having a dominant wavelength that is longer than the selected dominant wavelength. The wavelength bins and number of LEDs are selected such that in operation the dominant wavelength of the combined light emitted by the source is the selected dominant wavelength. Lighting arrangements and light emitting devices incorporating such light sources are disclosed.

Abstract: A semiconductor device is made by forming a conductive layer over a first sacrificial carrier. A solder bump is formed over the conductive layer. A no-flow underfill material is deposited over the first carrier, conductive layer, and solder bump. A semiconductor die or component is compressed into the no-flow underfill material to electrically contact the conductive layer. A surface of the no-flow underfill material and first solder bump is planarized. A first interconnect structure is formed over a first surface of the no-flow underfill material. The first interconnect structure is electrically connected to the solder bump. A second sacrificial carrier is mounted over the first interconnect structure. A second interconnect structure is formed over a second side of the no-flow underfill material. The second interconnect structure is electrically connected to the first solder bump. The semiconductor devices can be stacked and electrically connected through the solder bump.

Abstract: A semiconductor package comprises a top package and a bottom package with fan-out interconnect structures. A plurality of inter-package connectors electrically connect the top package and the bottom package, and are located near a perimeter of the semiconductor package. A first material is located in a space delimited by a lower surface of the top package, an upper surface of the bottom package, and the inner-most inter-package connectors of the semiconductor package, wherein the first material partially fills the space. A second material different from the first material encapsulates the inter-package connectors.

Abstract: Embodiments disclosed herein provide for a circuit including first die having an active side and a backside, wherein the first die is flip-chip mounted to a carrier. The circuit also includes a second die stacked on the backside of the first die, wherein the second die is stacked on the first die such that a backside of the second die is facing the backside of the first die and an active side of the second die faces away from the first die.

Abstract: A semiconductor device includes a carrier with an interface layer applied over the carrier. The interface layer can include non-conductive paste or non-conductive film. A plurality of semiconductor die is mounted to the carrier and interface layer by pressing the semiconductor die to the carrier and interface layer for one second or less, and simultaneously thermal compression bonding multiple semiconductor die to the carrier and interface layer for 5-10 seconds. By pressing the semiconductor die to the interface layer for a short period of time and then simultaneously thermal compression bonding multiple semiconductor die to the interface layer for a second longer period of time, the overall throughput of die bonding increases to process more die per unit of time. An encapsulant is deposited over the semiconductor die. The carrier is removed and interconnect structure is formed over the semiconductor die and encapsulant.

Abstract: An embodiment method for forming a semiconductor package includes attaching a first die to a first carrier, depositing a first isolation material around the first die, and after depositing the first isolation material, bonding a second die to the first die. Bonding the second die to the first die includes forming a dielectric-to-dielectric bond. The method further includes removing the first carrier and forming fan-out redistribution layers (RDLs) on an opposing side of the first die as the second die. The fan-out RDLs are electrically connected to the first die and the second die.

Abstract: Technologies are generally described for increase of spacing between source and drain regions of a vertical high voltage transistor without a significant corresponding increase in the die size. In some examples, active silicon (at drain potential) may be removed at an edge of the die in the scribe grid so that the active silicon is approximately below a surface of the edge termination formed by a region of deep dielectric filled trenches. The recessed drain region at the edge of the die may increase a flashover distance without appreciably increasing the die size. Thus, a distance between the recessed drain region and the surface source region may be increased by a combination of vertical and lateral spacing resulting in a smaller overall die size and smaller parasitic capacitances when operated with substantially the same operating voltage.

Abstract: In the semiconductor device including the off transistor serving as an ESD protection element and an output element between a first external connection terminal and a second external connection terminal connected to a VSS, a seal ring wire is connected in parallel, by a connection wire, to a first internal wire extending from the second external connection terminal to the source of the off transistor, and a parasitic resistance of the first internal wire is smaller than a parasitic resistance of a second internal wire connecting the source of the off transistor and a source of the output element to each other.

Abstract: A method of forming a semiconductor device including the steps of forming an electrically programmable fuse (e-fuse) on an isolation region and a transistor on an active region of a wafer, wherein forming the transistor includes forming a dummy gate above a substrate, removing the dummy gate and forming a metal gate in place of the dummy gate, and forming the e-fuse includes forming a metal-containing layer above the isolation region, forming a semiconductor layer on the metal-containing layer during the process of forming the dummy gate and of the same material as the dummy gate, forming a hard mask layer on the semiconductor layer formed on the metal-containing layer, and forming contact openings in the hard mask layer and semiconductor layer during the process of removing the dummy gate.

Abstract: A semiconductor device comprising: a first, a second and a third conductive layer; the second conductive layer being located between the first and third conductive layers; wherein respective regions of the first and second conductive layers form a first capacitor; and respective regions of the second and third conductive layers form a second capacitor.

Abstract: In an example, a capacitor in an integrated circuit (IC), includes: a first finger capacitor formed in at least one layer of the IC having a first bus and a second bus; a second finger capacitor formed in the at least one layer of the IC having a first bus and a second bus, where a longitudinal edge of the second bus of the second finger capacitor is adjacent a longitudinal edge of the first bus of the first finger capacitor and separated by a dielectric gap; and a first metal segment formed on a first layer above the at least one layer, the first metal segment being electrically coupled to the first bus of the first finger capacitor and increasing a width and a height of the first bus of the first finger capacitor.

Abstract: Embodiments of a semiconductor device structure and a method for forming the same are provided. The semiconductor device structure includes a substrate and a first metal gate structure formed over the substrate. The first metal gate structure has a first width. The semiconductor device structure further includes a first contact formed adjacent to the first metal gate structure and a second metal gate structure formed over the substrate. The second metal gate structure has a second width smaller than the first width. The semiconductor device structure further includes an insulating layer formed over the second metal gate structure and a second contact self-aligned to the second metal gate structure.

Abstract: The present disclosure provides a semiconductor device, which includes a compensation area which includes p-regions and n-regions, and a plurality of transistor cells on the compensation area. Each of the plurality of transistor cells includes a source region, a body region, a gate and an interlayer dielectric, and a source metallization layer arranged on the interlayer dielectric. The semiconductor device further includes an additional n-doping region that is provided on top of the n-regions between two neighboring body regions, and a source plug which fills a contact hole formed through the interlayer dielectric between the source and body region and the source metallization layer, so as to electrically connect the source and body region and the source metallization layer.

Abstract: A semiconductor device and a method of forming the same, the semiconductor device include a substrate, and a first transistor, a second transistor and a third transistor all disposed on the substrate. The first transistor includes a first channel, and a first barrier layer and a first work function layer stacked with each other on the first channel. The second transistor includes a second channel, and a second barrier layer and a second work function layer stacked with each other. The third transistor includes a third channel and a third barrier layer and a third work function layer stacked with each other on the third channel, wherein the first barrier layer, the second barrier layer and the third barrier layer have different nitrogen ratio. The first, the second and the third transistors have different threshold voltages, respectively.

Abstract: A fabrication method of semiconductor device having metal gate includes providing a substrate, successively forming a gate insulating layer and a bottom barrier layer on the surface of the substrate, forming a work function layer covering the bottom barrier layer, removing the work function layer, and forming a top barrier layer on the bottom barrier layer to be directly contact with the bottom barrier layer, and forming a metal layer on the top bottom barrier layer.

Abstract: A method includes forming a set of fins composed of a first semiconductor material. The method further heats the set of fins to condense the fins and cause growth of a layer of oxide on vertical sidewalls thereof, masking a first sub-set of the fins, forming a plurality of voids in the oxide by removing a second sub-set of fins, where each void has a three-dimensional shape and dimensions that correspond to a three dimensional shape and dimensions of a corresponding removed fin from the second sub-set, and epitaxially growing in the voids a third sub-set of fins. The third sub-set of fins is composed of a second semiconductor material that differs from the first semiconductor material. Each fin of the third subset has a three dimensional shape and dimensions of a corresponding removed fin from the second sub-set. At least one structure formed by the method is also disclosed.

Abstract: Asymmetric, semiconductor memory cells, arrays, devices and methods are described. Among these, an asymmetric, bi-stable semiconductor memory cell is described that includes: a floating body region configured to be charged to a level indicative of a state of the memory cell; a first region in electrical contact with the floating body region; a second region in electrical contact with the floating body region and spaced apart from the first region; and a gate positioned between the first and second regions, such that the first region is on a first side of the memory cell relative to the gate and the second region is on a second side of the memory cell relative to the gate; wherein performance characteristics of the first side are different from performance characteristics of the second side.

Abstract: Techniques for providing a semiconductor memory device are disclosed. In one particular exemplary embodiment, the techniques may be realized as a semiconductor memory device including a plurality of memory cells arranged in an array of rows and columns. Each memory cell including a first region, a second region, and a body region capacitively coupled to at least one word line and disposed between the first region and the second region. Each memory cell also including a third region, wherein the third region may be doped differently than the first region, the second region, and the body region.

Abstract: An apparatus includes a first metal layer coupled to a bit cell. The apparatus also includes a third metal layer including a write word line that is coupled to the bit cell. The apparatus further includes a second metal layer between the first metal layer and the third metal layer. The second metal layer includes two read word lines coupled to the bit cell.

Abstract: A method of forming a NAND flash memory includes etching between word lines to expose isolation material in shallow trench isolation (STI) trenches while active areas between word lines remain covered, then forming protective sleeves at locations over exposed isolation material. Subsequently, with the protective sleeves in place, isotropic etching of isolation material forms an air gap extending continuously between the protective sleeves along an individual STI trench.

Abstract: A dielectric layer extending over a substrate has alternating first and second trenches extending in a first direction. The first trenches have a first shape in cross section along a plane that is perpendicular to the first direction and the second trenches have a second shape in cross section along the plane. Bit lines are located in at least the first trenches.

Abstract: Provided are a semiconductor device and a method of manufacturing the same. The semiconductor device may include a dummy structure formed on a peripheral region of a substrate, and insulating spacers configured to pass through the dummy structure and protrude from an upper surface of the dummy structure. The semiconductor device may include first contact plugs configured to pass through the insulating spacers and protrude from upper surfaces of the insulating spacers.

Abstract: A method of fabricating a semiconductor device, such as a three-dimensional NAND memory string, includes forming a carbon etch stop layer having a first width over a major surface of a substrate, forming a stack of alternating material layers over the etch stop layer, etching the stack to the etch stop layer to form a memory opening having a second width at a bottom of the memory opening that is smaller than the width of the etch stop layer, removing the etch stop layer to provide a void area having a larger width than the second width of the memory opening, forming a memory film over a sidewall of the memory opening and in the void area, and forming a semiconductor channel in the memory opening such that the memory film is located between the semiconductor channel and the sidewall of the memory opening.

Abstract: Resistance of a semiconductor channel in three-dimensional memory stack structures can be reduced by forming a metal-semiconductor alloy region between a vertical semiconductor channel and a horizontal semiconductor channel located within a substrate. The metal-semiconductor alloy region can be formed by recessing a portion of the semiconductor material layer in the semiconductor substrate underneath a memory opening after formation of a memory film, selectively depositing a metallic material in the recess region, depositing a vertical semiconductor channel, and reacting the deposited metallic material with an adjacent portion of the semiconductor material layer and the vertical semiconductor channel. A sacrificial dielectric material layer can be formed on the memory film prior to the selective deposition of the metallic material.

Abstract: A 3D non-volatile memory device includes a pipe gate, at least one first channel layer including a first pipe channel layer formed in the pipe gate and a pair of first source side channel layer and first drain side channel layer connected to the first pipe channel layer, and at least one second channel layer including a second pipe channel layer formed in the pipe gate and positioned over the first pipe channel layer and a pair of second source side channel layer and second drain side channel layer connected to the second pipe channel layer.

Abstract: According to one embodiment, a semiconductor memory device includes a substrate; an insulating layer provided on the substrate; a conductive layer provided on the insulating layer; a stacked body provided on the conductive layer and including a plurality of electrode layers and a plurality of insulating layers respectively provided among the plurality of electrode layers; a columnar section piercing through the stacked body to reach the conductive layer and extending in a first direction in which the stacked body is stacked; and a source layer. The columnar section includes a channel body and a charge storage film provided between the channel body and the respective electrode layers. The conductive layer includes a first film having electric conductivity and in contact with the lower end portion of the channel body; and an air gap provided to be covered by the first film.