Abstract: An integrated circuit includes a substrate, a bottom electrode, a dielectric layer, a metal-containing compound layer, a resistance switching element, and a top electrode. The bottom electrode is over the substrate, the bottom electrode having a bottom portion and a top portion over the bottom portion. The bottom portion of the bottom electrode has a sidewall slanted with respect to a sidewall of the top portion of the bottom electrode. The dielectric layer surrounds the bottom portion of the bottom electrode. The metal-containing compound layer surrounds the top portion of the bottom electrode. A top end of the sidewall of the bottom portion of the bottom electrode is higher than a bottom surface of the metal-containing compound layer. The resistance switching element is over the bottom electrode. The top electrode is over the resistance switching element.

Abstract: A device includes a package substrate, an interposer having a first side bonded to the package substrate, a first die bonded to a second side of the interposer, the second side being opposite the first side, a ring on the package substrate, where the ring surrounds the first die and the interposer, a molding compound disposed between the ring and the first die, where the molding compound is in physical contact with the ring, and a plurality of thermal-conductive layers over and in physical contact with the molding compound and the first die, where the molding compound is disposed between the plurality of thermal-conductive layers and the ring.

Abstract: A method includes: applying a first solution to a semiconductor structure of a semiconductor device to form a first coating, the semiconductor structure including a feature and the trench, the first coating being formed in the trench and over the feature, the first solution containing a metal-containing solute; heating the first coating in a multi-step procedure to turn the first coating into a first film, the multi-step procedure including heating at a first temperature, followed by heating at a second temperature not lower than the first temperature; applying a second solution onto the first film to form a second coating, the second solution containing the metal-containing solute; and heating the second coating in a multi-step procedure to turn the second coating into a second film, the multi-step procedure including heating at a third temperature, followed by heating at a fourth temperature not lower than the third temperature.

Abstract: A semiconductor package including a cooling system and a method of forming are provided. The semiconductor package may include an interposer, one or more package components bonded to the interposer, an encapsulant on the interposer, and a cooling system over the one or more package components. The cooling system may include one or more metal layers on top surfaces of the one or more package components, first metal pins on the one or more metal layers, second metal pins, wherein each of the second metal pins may be bonded to a corresponding one of the first metal pins by solder, and a first lid over the second metal pins, wherein the first lid may include openings.

Abstract: Provided are a semiconductor device and a method of forming the same. The semiconductor device includes a semiconductor device. The semiconductor device includes a substrate including a plurality of fins, a plurality of semiconductor nanosheets stacked on the plurality of fins, a plurality of gate stacks wrapping the plurality of semiconductor nanosheets, an isolation structure around the plurality of fins, and a separator structure on the isolation structure to separate the plurality of gate stacks from each other. The separator structure includes a body and a cap on the body. The cap includes a first portion and a second portion. Sidewalls and bottom of the second portion is wrapped by the first portion.

Abstract: A semiconductor structure includes a substrate including a first region and a second region, a first channel layer disposed in the first region and a second channel layer disposed in the second region, a first dielectric layer disposed on the first channel layer and a second dielectric layer disposed on the second channel layer, and a first gate electrode disposed on the first dielectric layer and a second gate electrode disposed on the second dielectric layer. The first channel layer in the first region includes Ge compound of a first Ge concentration, the second channel layer in the second region includes Ge compound of a second Ge concentration. The first Ge concentration in the first channel layer is greater than the second Ge concentration in the second channel layer.

Abstract: The present disclosure relates to an integrated chip comprising a substrate. A first conductive wire is over the substrate. A second conductive wire is over the substrate and is adjacent to the first conductive wire. A first dielectric cap is laterally between the first conductive wire and the second conductive wire. The first dielectric cap laterally separates the first conductive wire from the second conductive wire. The first dielectric cap includes a first dielectric material. A first cavity is directly below the first dielectric cap and is laterally between the first conductive wire and the second conductive wire. The first cavity is defined by one or more surfaces of the first dielectric cap.

Abstract: A method for forming an underfill structure and semiconductor packages including the underfill structure are disclosed. In an embodiment, the semiconductor package may include a package including an integrated circuit die; an interposer bonded to the integrated circuit die by a plurality of die connectors; and an encapsulant surrounding the integrated circuit die. The semiconductor package may further include a package substrate bonded to the interposer by a plurality of conductive connectors; a first underfill between the package and the package substrate, the first underfill having a first coefficient of thermal expansion (CTE); and a second underfill surrounding the first underfill, the second underfill having a second CTE less than the first CTE.

Abstract: The present disclosure relates to an integrated chip including a substrate. A first conductive wire is within a first dielectric layer that is over the substrate. A first etch-stop layer is over the first dielectric layer. A second etch-stop layer is over the first etch-stop layer. A conductive via is within a second dielectric layer that is over the second etch-stop layer. The conductive via extends through the second etch-stop layer and along the first etch-stop layer to the first conductive wire. A first lower surface of the second etch-stop layer is on a top surface of the first etch-stop layer. A second lower surface of the second etch-stop layer is on a top surface of the first conductive wire.

Abstract: Half Quad Photodiode (QPD) for improving QPD channel imbalance. In one embodiment, an image sensor includes a plurality of pixels arranged in rows and columns of a pixel array that is disposed in a semiconductor material. Each pixel includes a plurality of subpixels. Each subpixel comprises a plurality of first photodiodes, a plurality of second photodiodes and a plurality of third photodiodes. The plurality of pixels are configured to receive incoming light through an illuminated surface of the semiconductor material. A plurality of small microlenses are individually distributed over individual first photodiodes and individual second photodiodes of each subpixel. A plurality of large microlenses are each distributed over a plurality of third photodiodes of each subpixel. A diameter of the small microlenses is smaller than a diameter of the large microlenses.

Abstract: A semiconductor device package comprises a semiconductor device, a first encapsulant surrounding the semiconductor device, a second encapsulant covering the semiconductor device and the first encapsulant, and a redistribution layer extending through the second encapsulant and electrically connected to the semiconductor device.

Abstract: The present disclosure relates to an integrated chip comprising a pair of first metal lines over a substrate. A first interlayer dielectric (ILD) layer is laterally between the pair of first metal lines. The first ILD layer comprises a first dielectric material. A pair of spacers are on opposite sides of the first ILD layer and are laterally separated from the first ILD layer by a pair of cavities. The pair of spacers comprise a second dielectric material. Further, the pair of cavities are defined by opposing sidewalls of the first ILD layer and sidewalls of the pair of spacers that face the first ILD layer.

Abstract: A semiconductor device includes a substrate, an interconnect layer disposed over the substrate and including a metal line, and a dielectric layer disposed on the interconnect layer and including a via contact. The via contact is electrically connected to the metal line and has a first dimension in a first direction greater than a second dimension in a second direction. The first direction and the second direction are perpendicular to each other, and are both perpendicular to a longitudinal direction of the via contact.

Abstract: In an embodiment, a device includes: an interposer; a first integrated circuit device bonded to the interposer with dielectric-to-dielectric bonds and with metal-to-metal bonds; a second integrated circuit device bonded to the interposer with dielectric-to-dielectric bonds and with metal-to-metal bonds; a buffer layer around the first integrated circuit device and the second integrated circuit device, the buffer layer including a stress reduction material having a first Young's modulus; and an encapsulant around the buffer layer, the first integrated circuit device, and the second integrated circuit device, the encapsulant including a molding material having a second Young's modulus, the first Young's modulus less than the second Young's modulus.

Abstract: The present disclosure provides a multi-scale three-dimensional (3D) engineering geological model construction system and method. A regional geological model of a target region, a site geological model of each engineering site, and a drilling geological model of each drilling well are constructed. The geological model of each drilling well is superimposed to the site geological model of the corresponding engineering site in the way of step-by-step superimposition, and the site geological model of each engineering site fused with the drilling geological model is superimposed to the regional geological model of the target region. Thus, multi-scale geological model fusion of drilling well, engineering site, and regional mountain is realized.

Abstract: An ultrasonic data transmission method, apparatus and system, a terminal device and a medium are provided. The method is applied to a transmitting terminal which includes at least two ultrasonic signal transmitting arrays. The method includes: a single-frequency ultrasonic coding signal of to-be-transmitted information corresponding to each ultrasonic signal transmitting array is respectively determined, ultrasonic codes of to-be-transmitted information corresponding to different ultrasonic signal transmitting arrays being different; and corresponding at least two single-frequency ultrasonic code signals are transmitted through the at least two ultrasonic signal transmitting arrays to a receiving terminal in a focusing mode, frequency bands of transmitting frequencies of different ultrasonic signal transmitting arrays being different.

Abstract: A Static Random Access Memory (SRAM) cell includes a write port including a first inverter including a first pull-up transistor and a first pull-down transistor, and a second inverter including a second pull-up transistor and a second pull-down transistor and cross-coupled with the first inverter; and a read port including a read pass-gate transistor and a read pull-down transistor serially connected to each. A first doped concentration of impurities doped in channel regions of the second pull-down transistor and the read pull-down transistor is greater than a second doped concentration of the impurities doped in a channel region of the first pull-down transistor, or the impurities are doped in the channel regions of the second pull-down transistor and the read pull-down transistor and are not doped in the channel region of the first pull-down transistor.

Abstract: A method, apparatus, and a non-transitory computer-readable storage medium for event detection are provided. The method may be applied to an electronic device. The electronic device may transmit a detection signal. The electronic device may receive an echo signal of the detection signal. The electronic device may acquire a feature value of the echo signal. The electronic device may calculate a decision parameter based on the feature value, and may determine, based on the decision parameter, that the electronic device is moving towards or away from a target object.

Abstract: A semiconductor device may include a bandgap circuit that outputs a reference voltage. The bandgap circuit may include a bandgap core circuit and a startup circuit coupled to the bandgap core circuit. The startup circuit may connect a voltage source to a node that corresponds to an output of the bandgap core circuit in response to the bandgap core circuit being initialized. The startup circuit may also disconnect the voltage source from the node in response to the output voltage being equal to or greater than a desired voltage (e.g., a threshold voltage) and one or more local voltages of the bandgap core circuit being equal to or greater than a local threshold voltage.

Abstract: Semiconductor devices and methods of manufacture are provided, in which an adhesive is removed from a semiconductor die embedded within an encapsulant, and an interface material is utilized to remove heat from the semiconductor device. The removal of the adhesive leaves behind a recess adjacent to a sidewall of the semiconductor, and the recess is filled.