Abstract: A semiconductor die may be coupled to a printed circuit board using a solder ball. The semiconductor die comprises a redistribution layer formed above a semiconductor chip, a polymer layer formed on the redistribution layer, and an Under Bump Metallurgy (UBM) layer formed on the polymer layer. The polymer layer comprises a plurality of vias, which electrically couple the UBM layer to the redistribution layer. The entire UBM layer may be deposited with a continuously flat upper surface for coupling to the solder ball. The plurality of vias may be positioned such that they are centered on a point that is not central to the UBM layer.

Abstract: An image sensor including a substrate having a first, a first device isolation region adjacent to the first surface and defining a unit pixel, a transfer gate on the first surface at an edge of the unit pixel, a photoelectric conversion part in the substrate and adjacent to a first side surface of the transfer gate, and a floating diffusion region in the substrate and adjacent to a second side surface of the transfer gate. The second side surface faces the first side surface. The first device isolation region is spaced apart from the second side surface. The substrate and the first device isolation region are doped with impurities having a first conductivity. A first impurity concentration of the first device isolation region is greater than a second impurity concentration of the substrate.

Abstract: A silver-indium transient liquid phase method of bonding a semiconductor device and a heat-spreading mount, and a semiconductor structure having a silver-indium transient liquid phase bonding joint are provided. With the ultra-thin silver-indium transient liquid phase bonding joint formed between the semiconductor device and the heat-spreading mount, its thermal resistance can be minimized to achieve a high thermal conductivity. Therefore, the heat spreading capability of the heat-spreading mount can be fully realized, leading to an optimal performance of the high power electronics and photonics devices.

Abstract: A package includes a first die, a second die, a first encapsulant, first through insulating vias (TIV), a second encapsulant, and second TIVs. The second die is stacked on the first die. The first encapsulant laterally encapsulates the first die. The first TIVs are aside the first die. The first TIVs penetrate through the first encapsulant and are electrically floating. The second encapsulant laterally encapsulates the second die. The second TIVs are aside the second die. The second TIVs penetrate through the second encapsulant and are electrically floating. The second TIVs are substantially aligned with the first TIVs.

Abstract: A method of manufacturing a device chip includes applying, from a front surface of a wafer formed with devices in a plurality of regions partitioned by a plurality of crossing division lines, a laser beam of such a wavelength as to be absorbed in the wafer along the division lines, to form V-shaped laser processed grooves along the division lines, the laser processed grooves becoming shallower toward outer sides in a width direction; adhering an adhesive tape to the front surface of the wafer formed with the laser processed grooves; and grinding the wafer held by a chuck table, with the adhesive tape interposed therebetween, from a back surface, to divide the wafer while thinning the wafer to a finished thickness, thereby forming a plurality of device chips having inclined surfaces at outside surfaces thereof.

Abstract: A semiconductor device package includes a first surface and a second surface opposite to the first surface. The semiconductor device package further includes a first supporting structure disposed on the first surface of the substrate and a second supporting structure disposed on the first surface of the substrate. The first supporting structure has a first surface spaced apart from the first surface of the substrate by a first distance. The second supporting structure has a first surface spaced apart from the first surface of the substrate by a second distance. The second distance is different from the first distance. The semiconductor device package further includes a first antenna disposed above the first surface of the substrate. The first antenna is supported by the first surface of the first supporting structure and the first surface of the second supporting structure.

Abstract: A method of manufacturing a semiconductor device according to example embodiments includes: sequentially forming first through third insulating layers on a substrate; forming an opening by etching the first through third insulating layers; forming a conductive layer configured in the opening; forming a fourth insulating layer in the opening after the forming of the conductive layer; and removing a portion of an edge region of the substrate after the forming of the fourth insulating layer.

Abstract: A stacking structure including a first die, a second die stacked on the first die, and a filling material is provided. The first die has a first bonding structure, and the first bonding structure includes first bonding pads and a first heat dissipating element. The second die has a second bonding structure, and the second bonding structure includes second bonding pads and a second heat dissipating element. The first bonding pads are bonded with the second bonding pads. The first heat dissipating element is connected to one first bonding pad of the first bonding pads and the second heat dissipating element is connected to one second bonding pad of the second bonding pads. The filling material is disposed over the first die and laterally around the second die. The first and second dies are bonded through the first and second bonding structures.

Abstract: A semiconductor package includes a chip including a pad; a first insulation pattern on the chip and exposing the pad; a redistribution layer (RDL) on an upper surface of the first insulation pattern and connected to the pad; a second insulation pattern on the upper surface of the first insulation pattern and including an opening exposing a ball land of the RDL and a patterned portion in the opening; an under bump metal (UBM) on upper surfaces of the second insulation pattern and patterned portion and filling the opening, the UBM including a first locking hole exposing an edge of an upper surface of the ball land; and a conductive ball on an upper surface of the UBM and including a first locking portion in the first locking hole. The first locking hole may be about 10% to about 50% of the area of the UBM upper surface.

Abstract: A through-hole electrode substrate includes a substrate including a through-hole extending from a first aperture of a first surface to a second aperture of a second surface, an area of the second aperture being larger than that of the first aperture, the through-hole having a minimum aperture part between the first aperture and the second aperture, wherein an area of the minimum aperture part in a planer view is smallest among a plurality of areas of the through-hole in a planer view, a filler arranged within the through-hole, and at least one gas discharge member contacting the filler exposed to one of the first surface and the second surface.

Abstract: One aspect of the invention is a method of manufacturing a connection structure, including disposing an adhesive layer between a first electronic member including a first substrate and a first electrode formed on the first substrate and a second electronic member including a second substrate and a second electrode formed on the second substrate, and pressure-bonding the first electronic member and the second electronic member via the adhesive layer such that the first electrode and the second electrode are electrically connected to each other, wherein the first electronic member further including an insulating layer formed on a side of the first electrode opposite to the first substrate, and the adhesive layer including: a first conductive particle being a dendritic conductive particle; and a second conductive particle being a conductive particle other than the first conductive particle and having a non-conductive core and a conductive layer provided on the core.

Abstract: A bottom emission microLED display includes a microLED disposed above a transparent substrate; a light guiding layer surrounding the microLED to controllably guide light generated by the microLED towards the transparent substrate; and a reflecting layer formed over the light guiding layer to reflect the light generated by the microLED downwards and to confine the light generated by the microLED to prevent the light from leaking upwards or sidewards.

Abstract: A nonvolatile memory device includes a memory cell region including first pads and a peripheral circuit region including second pads. The regions comprises switches that are electrically connected with the pads, respectively, a test signal generator that generates test signals and to transmit the test signals to the switches, internal circuits that receive first signals through the pads and the switches, to perform operations based on the first signals, and to output second signals through the switches and the pads based on a result of the operations, and a switch controller that controls the switches so that the pads communicate with the test signal generator during a test operation and that the pads communicate with the internal circuits after a completion of the test operation. The peripheral circuit region is vertically connected to the memory cell region by the first metal pads and the second metal pads directly.

Abstract: Microelectronic assemblies, and related devices and methods, are disclosed herein. For example, in some embodiments, a microelectronic assembly may include: a first die having a first surface and an opposing second surface, first conductive contacts at the first surface of the first die, and second conductive contacts at the second surface of the first die; and a second die having a first surface and an opposing second surface, and first conductive contacts at the first surface of the second die; wherein the second conductive contacts of the first die are coupled to the first conductive contacts of the second die by interconnects, the second surface of the first die is between the first surface of the first die and the first surface of the second die, and a footprint of the first die is smaller than and contained within a footprint of the second die.

Abstract: This member connection method includes: a cutting step of forming cutting lines C in an adhesive layer at predetermined intervals at least in a width direction of an adhesive tape and making segments of the adhesive layer divided by the cutting lines C continuous at least in a lengthwise direction of the adhesive tape; a transfer step of disposing the segments to face a connection surface of one member to be connected, pressing a heating and pressing tool having an arbitrary pattern shape against the adhesive tape from a separator side and selectively transferring the segments to the one member to be connected; and a connection step for connecting another member to be connected to the one member to be connected via the segments transferred to the one member to be connected.

Abstract: A package structure including at least one die laterally encapsulate by an encapsulant, a bonding film and an interconnect structure is provided. The bonding film is located on a first side of the encapsulant, and the bonding film includes a first alignment mark structure. The package structure further includes a semiconductor material block located on the bonding film. The interconnect structure is located on a second side of the encapsulant opposite to the first side, and the interconnect structure includes a second alignment mark structure. A location of the first alignment mark structure vertically aligns with a location of the second alignment mark structure.

Abstract: A wafer-level packaging based module includes an antenna board and a chip board. The antenna board includes at least one antenna layer with introduced antenna element and a shielding layer with introduced shielding element in the area of the at least one antenna element opposite to the antenna layer. The chip board includes a contacting layer, a rewiring layer opposite to the contacting layer and the shielding layer having at least one shielding element arranged on the rewiring layer. A chip layer having at least one chip is arranged between the contacting layer and the rewiring layer. Further, the chip layer includes at least one via connecting the contacting layer to the rewiring layer.

Abstract: The present application discloses a semiconductor device with a recessed pad layer and a method for fabricating the semiconductor device. The semiconductor device includes a first die, a second die positioned on the first die, a pad layer positioned in the first die, a filler layer including an upper portion and a recessed portion, and a barrier layer positioned between the second die and the upper portion of the filler layer, between the first die and the upper portion of the filler layer, and between the pad layer and the recessed portion of the filler layer. The upper portion of the filler layer is positioned along the second die and the first die, and the recessed portion of the filler layer is extending from the upper portion and positioned in the pad layer.

Abstract: A semiconductor package including a first device layer including first semiconductor devices, a first cover insulating layer, and first through-electrodes passing through at least a portion of the first device layer, a second device layer second semiconductor devices, a second cover insulating layer, and second through-electrodes passing through at least a portion of the second device layer, the second semiconductor devices vertically overlapping the first semiconductor devices, respectively, the second cover insulating layer in contact with the first cover insulating layer a third device layer including an upper semiconductor chip, the upper semiconductor chip vertically overlapping both at least two of first semiconductor devices and at least two of the second semiconductor devices, and device bonded pads passing through the first and second cover insulating layers, the device bonded pads electrically connecting the first and second through-electrodes to the upper semiconductor chip may be provided.

Abstract: A method for fastening a semiconductor chip on a substrate and an electronic component are disclosed. In an embodiment a method includes providing a semiconductor chip, applying a solder metal layer sequence on the semiconductor chip, providing a substrate, applying a metallization layer sequence on the substrate, applying the semiconductor chip on the substrate via the solder metal layer sequence and the metallization layer sequence and heating the applied semiconductor chip on the substrate for fastening the semiconductor chip on the substrate. The solder metal layer may include a first metallic layer comprising an indium-tin alloy, a barrier layer arranged above the first metallic layer and a second metallic layer comprising gold arranged between the barrier layer and the semiconductor chip, wherein an amount of substance of the gold in the second metallic layer is greater than an amount of substance of tin in the first metallic layer.