Abstract: A method for fabricating a semiconductor device includes providing a substrate including a cell region including a bit line structure, a bit line spacer and a lower electrode and a peripheral circuit region including first to third impurity regions, forming an interlayer insulating film on the peripheral circuit region, forming a first metal layer on the interlayer insulating film, forming a first trench and a second trench in the first metal layer between the first and second impurity regions, the second trench is disposed between the second and third impurity regions and exposes the interlayer insulating film, forming a first capping pattern on the first trench to form an air gap in the first trench, filling the second trench with a first insulating material, and forming, on the first metal layer, a contact connected to the third impurity region.

Abstract: A semiconductor device has a substrate and a lightly doped drain (LDD) region formed in the substrate. A superjunction is formed in the LDD region.

Abstract: A color image sensor including an array of pixels is formed in a semiconductor layer having a back side that receives an illumination. Insulated conductive walls penetrate into the semiconductor layer from the back side and separate the pixels from one another. For each pixel, a color pixel penetrates into from 5 to 30% of a thickness of the semiconductor layer from the back side and occupies at least 90% of the surface area delimited by the walls. An electrically-conductive layer extends from the lateral wall of the filter all the way to the walls.

Abstract: A microLED display panel includes a substrate being divided into a plurality of sub-regions for supporting microLEDs, and a plurality of drivers being correspondingly disposed on surfaces of the sub-regions respectively. In one embodiment, a top surface of the substrate has a recess for accommodating the driver.

Abstract: A sensor device includes a first substrate of semiconductor material having opposing first and second surfaces, photodetectors configured to receive light impinging on the first surface, and first contact pads each exposed at both the first and second surfaces and electrically coupled to at least one of the photodetectors. A second substrate comprises opposing first and second surfaces, electrical circuits, a second contact pads each disposed at the first surface of the second substrate and electrically coupled to at least one of the electrical circuits, and a plurality of cooling channels formed as first trenches extending into the second surface of the second substrate but not reaching the first surface of the second substrate. The first substrate second surface is mounted to the second substrate first surface such that each of the first contact pads is electrically coupled to at least one of the second contact pads.

Abstract: A light receiving region includes a plurality of light detecting sections 10. The light detecting sections 10 has a second contact electrode 4A. The second contact electrode 4A is arranged at a position overlapping a first contact electrode 3A, so as to contact the first contact electrode. Further, a resistive layer 4B is continued to the second contact electrode 4A.

Abstract: A device includes a semiconductor chip, a plurality of planar metallization layers arranged over a main surface of the semiconductor chip, and a passive component including windings, wherein each of the windings is formed in one of the plurality of planar metallization layers.

Abstract: A photo diode includes a pixel unit, a photo conversion layer, and a dielectric layer. The pixel unit includes a pair of pixels. The photo conversion layer is above the pixel unit and has a pair of portions, each of which corresponds to a respective one of the pixels. The dielectric layer is between the portions of the photo conversion layer. A method of manufacturing the photo diode is also disclosed.

Abstract: A method forming an interconnect structure includes depositing a first solder bump on a chip; depositing a second solder bump on a laminate, the second solder bump including a nickel copper colloid surrounded by a nickel or copper shell and suspended in a tin-based solder; aligning the chip with the laminate; performing a first reflow process to join the chip to the laminate; depositing an underfill material around the first solder bump and the second solder bump; and performing a second reflow process at a temperature that is lower than the first reflow process to convert the first solder bump and the second solder bump to an all intermetallic interconnect; wherein depositing the underfill material is performed before or after performing the second reflow process.

Abstract: A technique relates to an assembly for a quantum computing device. A quantum bus plane includes a first set of recesses. A readout plane includes a second set of recesses. A block is positioned to hold the readout plane opposite the quantum bus plane, such that the first set of recesses opposes the second set of recesses. A plurality of qubit chips are included where each has a first end positioned in the first set of recesses and has a second end positioned in the second set of recesses.

Abstract: A stacked chip layout includes a central processing chip; and a first active circuit block over the central processing chip. The stacked chip layout further includes a second active circuit block over the first active circuit. A center of the second active circuit block is offset from a center of the first active circuit block, the second active circuit block overlaps the first active circuit block in a partial overlap area, and the second active circuit block exposes a portion of the first active circuit block. The stacked chip layout further includes a local conductive element electrically connecting the first active circuit block to the second active circuit block. The local conductive element is within the partial overlap area.

Abstract: Disclosed is a method of forming back end of the line (BEOL) metal levels with improved dielectric capping layer to metal wire adhesion. The method includes process step(s) designed to address dielectric capping layer to metal wire adhesion, when the metal wire(s) in a given metal level are relatively thick. These process step(s) can include, for example: (1) selective adjustment of the deposition tool used to deposit the dielectric capping layer onto metal wires based on the pattern density of the metal wires in order to ensure that those metal wires actually achieve a temperature between 360° C.-400° C.; and/or (2) deposition of a relatively thin dielectric layer on the dielectric capping layer prior to formation of the next metal level in order to reduce the tensile stress of the metal wire(s) below without causing delamination. Also disclosed is an IC chip formed using the above-described method.

Abstract: Structures and formation methods of a chip package are provided. The method includes disposing a semiconductor die over a carrier substrate and forming a protection layer over the carrier substrate to surround the semiconductor die. The method also includes forming a dielectric layer over the protection layer and the semiconductor die. The method further includes cutting an upper portion of the dielectric layer to improve flatness of the dielectric layer. In addition, the method includes forming a conductive layer over the dielectric layer after cutting the upper portion of the dielectric layer.

Abstract: According to the present disclosure, an organic light-emitting diode device is disclosed with an organic light-emitting diode having a first main surface and a second main surface lying opposite the first main surface, an optically functional device having a first hollow space and a second hollow space, and a control element. The first hollow space is arranged on or over the first main surface, and the second hollow space is arranged below the second main surface. The first hollow space and the second hollow space are connected to one another by means of a fluid connection. An optically functional fluid is arranged in the optically functional device. The control element is configured to move the optically functional fluid to and fro between the first hollow space and the second hollow space.

Abstract: A device layer of an integrated circuit device includes a semiconductor active layer spanning a plurality of device regions. Each of the device regions has a heating element, a temperature sensor, and bioFETs in the device layer. The bioFETs have source/drain regions and channel regions in the semiconductor active layer and fluid gates exposed on a surface for fluid interfacing on one side of the device layer. A multilayer metal interconnect structure is disposed on the opposite side of the device layer. This structure places the heating elements in proximity to the fluid gates enabling localized heating, precision heating, and multiplexed temperature control for multiplexed bio-sensing applications.

Abstract: An OLED microdisplay comprising a substrate, a pixel array and a patterned conductive layer underneath the anode pad array to form an effective ground plane in order to greatly reduce or eliminate electrical cross-talk between pixels, and a method for fabricating same.

Abstract: A method of fabricating an integrated circuit is disclosed. The method comprises defining a multi-layer semiconductor device structure on a substrate using standard cells, defining an input port on the M0OD or PO layer of the semiconductor device structure and an output port on the M0OD layer, and defining a metal-1 layer over the M0OD and PO layers, the metal-1 layer having a first set of conduction paths and a second set of conduction paths. The method further comprises defining a metal-2 layer over the metal-1 layer and configuring the first set of metal-1 conduction paths and the metal-2 conduction paths to interconnect circuit components in different cells, wherein inter cell connections in the semiconductor device structure are made using the first set of metal-1 conduction paths or a combination of the first set of metal-1 and the metal-2 conduction paths.

Abstract: A method for manufacturing a light emitting device, having mounting a light emitting element on a board, forming a phosphor layer that contains a phosphor by spraying on surfaces of the board and the light emitting element after the mounting of the light emitting element; and forming a cover layer that contains at least one type of light reflecting material and light blocking material on a surface of the phosphor layer over the board.

Abstract: Semiconductor structures include a patterned interlayer dielectric overlaying a semiconductor substrate. The interlayer dielectric includes a first dielectric layer and at least one additional dielectric layer disposed on the first dielectric layer, wherein the patterned interlayer dielectric comprises at least one opening extending through the interlayer dielectric to the semiconductor substrate. Chemically enriched regions including ions of Si, P, B, N, O and combinations thereof are disposed in surfaces of the first dielectric layer and the at least one dielectric layer defined by the at least one opening. Also described are methods of for forming an interconnect structure in a semiconductor structure.

Abstract: A semiconductor device includes a semiconductor substrate, a first metal layer, an insulation layer, an organic layer, and a second metal layer. The first metal layer, the insulation layer, the organic layer, and the second metal layer are sequentially stacked on a surface of the semiconductor substrate. The first metal layer and the second metal layer are electrically connected to each other through vias formed in the insulation layer and the organic layer. The second metal layer includes an electrode pad at a position corresponding to the positions of the vias. At the interface between the surface of the semiconductor substrate and the first metal layer, a patch portion having a trapezoidal cross-sectional shape is disposed directly below the vias.