Abstract: Embodiments of semiconductor devices and methods for forming the semiconductor devices are disclosed. In an example, a method for forming device openings includes forming a material layer over a first region and a second region of a substrate, the first region being adjacent to the second region, forming a mask layer over the material layer, the mask layer covering the first region and the second region, and forming a patterning layer over the mask layer. The patterning layer covers the first region and the second region and including openings corresponding to the first region. The plurality of openings includes a first opening adjacent to a boundary between the first region and the second region and a second opening further away from the boundary. Along a plane parallel to a top surface of the substrate, a size of the first opening is greater than a size of the second opening.

Abstract: The present disclosure describes a metal-oxide-semiconductor field-effect transistor (MOSFET) device. The MOSFET device includes a first-type substrate, a deep-second-type well in the first-type substrate, a first-type well over the deep-second-type well, and a second-type well over the deep-second-type well. The second-type well and the deep-second-type well form an enclosed space that includes the first-type well. The MOSFET also includes an embedded semiconductor region (ESR) in a vicinity of the enclosed space. The ESR includes a dopant concentration lower than at least one of a dopant concentration of the first-type well, a dopant concentration of the second-type well, and a dopant concentration of the deep-second-type well.

Abstract: A memory array comprises vertically-alternating tiers of insulative material and memory cells. The memory cells individually comprise a transistor and a capacitor. The capacitor comprises a first electrode electrically coupled to a source/drain region of the transistor. The first electrode comprises an annulus in a straight-line horizontal cross-section and a capacitor insulator radially inward of the first electrode annulus. A second electrode is radially inward of the capacitor insulator. A capacitor-electrode structure extends elevationally through the vertically-alternating tiers. Individual of the second electrodes of individual of the capacitors are electrically coupled to the elevationally-extending capacitor-electrode structure. A sense line is electrically coupled to another source/drain region of multiple of the transistors that are in different memory-cell tiers. Additional embodiments and aspects are disclosed, including methods.

Abstract: A semiconductor device that can detect temperature appropriately is provided. A semiconductor device provided with a semiconductor substrate in which one or more transistor portions and one or more diode portions are provided is provided, including: a temperature detecting portion provided above the top surface of the semiconductor substrate and having a longitudinal side in a predetermined longitudinal direction; a top surface electrode provided above the top surface of the semiconductor substrate; and one or more external lines that have a connecting part connected with the top surface electrode and electrically connect the top surface electrode to a circuit outside the semiconductor device. The temperature detecting portion extends across the one or more transistor portions and the one or more diode portions in the longitudinal direction, and the connecting part of at least one of the external lines is arranged around the temperature detecting portion when seen from above.

Abstract: A display device and a via-hole electrical connection structure are provided. The display device includes a substrate, a light-emitting device on the substrate and in a display region, and a circuit board at a side of the substrate away from the light-emitting device; and the display device further includes a via hole passing through the substrate, and the circuit board is electrically connected with the light-emitting device through the via hole.

Abstract: A method and apparatus for fabricating sensor chip assemblies. A photodetector wafer and an optics wafer are bonded to each other. Photodetectors are formed on the photodetector wafer. A circuit wafer is bonded to the photodetector wafer that is bonded to the optics wafer after forming the photodetectors on the photodetector wafer.

Abstract: In an embodiment, a device includes: a conductive shield on a first dielectric layer; a second dielectric layer on the first dielectric layer and the conductive shield, the first and second dielectric layers surrounding the conductive shield, the second dielectric layer including: a first portion disposed along an outer periphery of the conductive shield; a second portion extending through a center region of the conductive shield; and a third portion extending through a channel region of the conductive shield, the third portion connecting the first portion to the second portion; a coil on the second dielectric layer, the coil disposed over the conductive shield; an integrated circuit die on the second dielectric layer, the integrated circuit die disposed outside of the coil; and an encapsulant surrounding the coil and the integrated circuit die, top surfaces of the encapsulant, the integrated circuit die, and the coil being level.

Abstract: Method and structures for forming vertical transistors with uniform fin thickness. A structure includes: a substrate, a plurality of fins over the substrate, a top and a bottom source/drain region in contact with the plurality of fins, respectively, where the bottom source/drain region has an alternating topography, and a bottom spacer in contact with the bottom source/drain region, where the bottom spacer conforms to the alternating topography of the bottom-source drain region.

Abstract: A vertical current mode solid state device comprising a connection pad and side walls comprising a metal-insulator-semiconductor (MIS) structure, wherein leakage current effect of the vertical device is limited through the side walls by biasing the MIS structure.

Abstract: A first insulating layer is disposed on a second surface of a semiconductor substrate, and has an opening. A second insulating layer is disposed on the second surface and separated from the first insulating layer. A stack includes, in sequence on the second surface, a side n-type epitaxial layer and first and second p-type epitaxial layers that are made of a gallium-nitride-based material. The stack has an outer side wall having a portion formed of the second p-type epitaxial layer, an inner side wall extending from the second insulating layer, and a top surface. The n-type contact layer is disposed on the top surface. The source electrode portion is in contact with the n-type contact layer on the top surface, and is in contact with the second p-type epitaxial layer on the outer side wall. A gate insulating film is disposed on the inner side wall.

Abstract: A power device package includes a substrate, a high side power device, a low side power device and a driver device. The substrate includes a top surface, a bottom surface and a plurality of vias that extend through the substrate. The high side and low side power devices are disposed on the top surface of the substrate and connected with each other. The driver device is disposed on the bottom surface of the substrate and electrically connected with the high side and low side power devices through the vias to drive the high side and low side power devices in response to a control signal. The distance between the driver device and the high side and low side power devices is determined by the thickness of the substrate such that that a parasitic inductance between the driver device and the high side power device or the low side power device is reduced.

Abstract: A light emitting device includes: a substrate (40); blue light emitting elements (10) arranged on the main surface of the substrate (40); and a phosphor sheet (30) containing a phosphor that is excited by emission light from the blue light emitting elements and emits excitation light, the phosphor sheet (30) being disposed above the blue light emitting elements (30), wherein the blue light emitting elements (10) includes first blue light emitting elements (11) which emit first emission light having a first wavelength taken as a peak wavelength of a light emission spectrum, and second blue light emitting elements (12) which emit second emission light having a second wavelength taken as a peak wavelength of a light emission spectrum, and the second wavelength being a longer wavelength than the first wavelength by a wavelength difference of at least 10 nm.

Abstract: A package structure including a semiconductor die, an insulating encapsulant, a redistribution layer and a plurality of conductive terminals is provided. The semiconductor die includes a semiconductor substrate, a plurality of conductive pads and a plurality of conductive strips. The conductive pads are disposed on and connected to the plurality of conductive pads, wherein each of the conductive strips is physically connected to at least two conductive pads. The insulating encapsulant is encapsulating the semiconductor die. The redistribution layer is disposed on the insulating encapsulant and the semiconductor die, wherein the redistribution layer is electrically connected to the plurality of conductive strips. The plurality of conductive terminals is disposed on the redistribution layer.

Abstract: The invention provides a semiconductor package. The semiconductor package includes a semiconductor die and a conductive pillar bump structure and a conductive plug. The semiconductor die has a die pad thereon. The conductive pillar bump structure is positioned overlying the die pad. The conductive pillar bump structure includes an under bump metallurgy (UBM) stack having a first diameter and a conductive plug on the UBM stack. The conductive plug has a second diameter that is different than the first diameter.

Abstract: A semiconductor device includes a semiconductor body having a main surface and a rear surface opposite the main surface, and a trench that extends from the main surface of the semiconductor body towards the rear surface, the trench having an upper trench portion and a lower trench portion, the trench having a width measured along a plane parallel to the main surface. The upper trench portion includes curved sidewalls that that bow outward from a bottom of the upper trench portion. The lower trench portion includes generally planar sidewalls that extend from bottom of the upper trench portion at a first depth into the semiconductor body along the first direction to a contact region. An electrically conductive contact electrode is within the trench, is electrically insulated from the semiconductor body along sidewalls of the trench, and electrically connects to the semiconductor body at a bottom of the trench.

Abstract: A method is provided for manufacturing a field effect transistor that includes a gate insulating layer and an electrode including a first conductive film and a second conductive film successively laminated on a predetermined surface of the gate insulating layer. The method includes forming an oxide film including element A, which is an alkaline earth metal, and element B, which is at least one of Ga, Sc, Y and a lanthanide, as the gate insulating layer; forming a first conductive film that dissolves in an organic alkaline solution on the oxide film; forming a second conductive film on the first conductive film; etching the second conductive film with an etching solution having a higher etch rate for the second conductive film as compared with that for the first conductive film; and etching the first conductive film with the organic alkaline solution using the second conductive film as a mask.

Abstract: A semi-floating gate transistor is implemented as a vertical FET built on a silicon substrate, wherein the source, drain, and channel are vertically aligned, on top of one another. Current flow between the source and the drain is influenced by a control gate and a semi-floating gate. Front side contacts can be made to each one of the source, drain, and control gate terminals of the vertical semi-floating gate transistor. The vertical semi-floating gate FET further includes a vertical tunneling FET and a vertical diode. Fabrication of the vertical semi-floating gate FET is compatible with conventional CMOS manufacturing processes, including a replacement metal gate process. Low-power operation allows the vertical semi-floating gate FET to provide a high current density compared with conventional planar devices.

Abstract: A method of forming a long-channel fin field effect device is provided. The method includes forming a trench in a substrate, forming a pedestal in the trench, wherein the pedestal extends above the surface of the substrate, forming a sacrificial pillar on the pedestal, forming a rounded top surface on the sacrificial pillar to form a sacrificial support structure, forming a fin material layer on the exposed surface of the sacrificial support structure, and removing the sacrificial support structure to leave a free-standing inverted U-shaped fin.

Abstract: A high voltage device includes: a semiconductor layer, an isolation structure, a drift oxide region, a well, a body region, a gate, at least one sub-gate, a source, a drain and a conductive connection structure. The drift oxide region is located on a drift region in an operation region. The sub-gate is formed on the drift oxide region in the operation region. The sub-gate is a rectangle shape extending along a width direction, and in parallel with the gate. A conductive connection structure connects the gate and the sub-gate.

Abstract: An array substrate includes: a base substrate; at least one first connection terminal, at least one second connection terminal, and at least one connection line, which are disposed on the base substrate and located in a non-display area of the array substrate, the at least one connection line being connected with the at least one first connection terminal and the at least one second connection terminal; at least one gate line disposed on the base substrate and located in a display area of the array substrate. The first connection terminal is for connecting with an IC, and the second connection terminal is for connecting with a flexible circuit board. A resistivity of at least a part of each of at least one of the at least one connection line is less than a resistivity of the at least one gate line.