Abstract: A magnetic tunnel junction (MTJ) is disclosed wherein first and second interfaces of a free layer (FL) with a first metal oxide (Hk enhancing layer) and second metal oxide (tunnel barrier), respectively, produce perpendicular magnetic anisotropy (PMA) to increase thermal stability. In some embodiments, a capping layer that is a conductive metal nitride such as MoN contacts an opposite surface of the Hk enhancing layer with respect to the first interface to reduce interdiffusion of oxygen and nitrogen compared with a TiN capping layer and maintain an acceptable resistance×area (RA) product. In other embodiments, the capping layer may comprise an insulating nitride such as AlN that is alloyed with a conductive metal to minimize RA. Furthermore, a metallic buffer layer may be inserted between the capping layer and Hk enhancing layer. As a result, electrical shorts are reduced and the magnetoresistive ratio is increased.

Abstract: An integrated device includes at least one MOS transistor having a plurality of cells. In each of one or more of the cells a disabling structure is provided. The disabling structure is configured to be in a non-conductive condition when the MOS transistor is switched on in response to a control voltage comprised between a threshold voltage of the MOS transistor and an intervention voltage of the disabling structure, or to be in a conductive condition otherwise. A system comprising at least one integrated device as above is also proposed. Moreover, a corresponding process for manufacturing this integrated device is proposed.

Abstract: A semiconductor device for reducing a switching loss includes a drain metal. A silicon substrate of a first conductive type is provided on the drain metal. An epitaxial layer of the first conductive type is provided on the silicon substrate of the first conductive type. A pillar of the first conductive type and a pillar of a second conductive type are arranged in the epitaxial layer of the first conductive type. A body region of the second conductive type is provided on a surface of each pillar. A heavily doped source region of the first conductive type and a heavily doped source region of the second conductive type are arranged in the body region of the second conductive type. A gate trench is formed in the pillar of the first conductive type. Discrete gate polycrystalline silicon is provided in the gate trench.

Abstract: A power semiconductor device comprises a semiconductor layer structure having a wide band-gap drift region having a first conductivity type, a gate trench having first and second opposed sidewalls that extend in a first direction in an upper portion of the semiconductor layer structure, first and second well regions having a second conductivity type in the upper portion of the semiconductor layer structure, the first well region comprising part of the first sidewall and the second well region comprising part of the second sidewall. A deep shielding region having the second conductivity type is provided underneath the gate trench, and a plurality of deep shielding connection patterns that have the second conductivity type are provided that electrically connect the deep shielding region to the first and second well regions. The deep shielding connection patterns are spaced apart from each other along the first direction.

Abstract: An IGBT capable of handling high-speed switching while reducing a leakage current of a semiconductor device including the IGBT is provided. The semiconductor device according to one embodiment includes an IGBT including a p-type collector layer on a back surface of a silicon substrate and a dislocation suppressing layer for forming a hetero junction with silicon in the p-type collector layer. The dislocation suppressing layer includes a silicon germanium (SiGe) layer.

Abstract: A semiconductor device according to an embodiment includes: a first trench and a second trench extending in a first direction; a first gate electrode in the first trench; a second gate electrode in the second trench; a first gate wire including a first portion extending in a second direction perpendicular to the first direction and a third portion extending in the second direction; a second gate wire including a first portion extending in the second direction and a third portion extending in the second direction; a first gate electrode pad; and a second gate electrode pad. The first portion of the second gate wire is between the first portion and the third portion of the first gate wire, and the third portion of the first gate wire is between the first portion and the third portion of the second gate wire.

Abstract: A circuit test structure includes an interposer for electrically connecting to a chip, wherein the interposer includes a conductive line, and the conductive line extends along at least two side of the interposer. The circuit test structure further includes a plurality of electrical connections to the conductive line. The circuit test structure further includes a testing site electrically connected to the conductive line, wherein the testing site is on an opposite surface of the interposer from the plurality of electrical connections.

Abstract: A Field Effect Transistor (FET) may include a semiconductor substrate having a first conductivity type, a semiconductor layer of the first conductivity type formed over the substrate, and a pair of doped bodies of a second conductivity type opposite the first conductivity type formed in the semiconductor layer. A trench filled with a trench dielectric is formed within a region between the doped bodies. The FET may be a Vertical Metal-Oxide-Semiconductor FET (VMOSFET) including a gate dielectric disposed over the region between the doped bodies and the trench, and a gate electrode disposed over the gate dielectric, wherein the trench operates to prevent breakdown of the gate dielectric, or the FET may be a Junction FET. The FET may be designed to operate at radio frequencies or under heavy-ion bombardment. The semiconductor substrate and the semiconductor layer may comprise a wide band-gap semiconductor such as silicon carbide.

Abstract: A semiconductor device structure is provided. The semiconductor device structure includes a semiconductor substrate and a first metal gate stack and a second metal gate stack over the semiconductor substrate. The first metal gate stack and the second metal gate stack are electrically isolated from each other, and the first metal gate stack has a curved edge facing the second metal gate stack. The semiconductor device structure also includes a dielectric layer surrounding the first metal gate stack and the second metal gate stack.

Abstract: A mounting device comprises a recognition mechanism and a control unit. The recognition mechanism recognizes a chip recognition mark and a substrate recognition mark through a mounting head and from above the mounting head and is movable in an in-plane direction of a substrate surface of a substrate. The control unit is connected to the recognition mechanism, calculates an amount of misalignment between a chip component and the substrate from position information about the chip recognition mark and the substrate recognition mark obtained from the recognition mechanism, and performs positioning by driving the mounting head and/or the substrate stage according to the amount of misalignment. The recognition mechanism has a chip recognition sensor for recognizing the chip recognition mark and a substrate recognition sensor for recognizing the substrate recognition mark provided independently so that focal positions thereof are different via a common optical axis path.

Abstract: A method includes removing a dummy gate to form a gate trench. A gate dielectric layer is deposited over a bottom and sidewalls of the gate trench. A first work function metal layer is deposited over the gate dielectric layer. A dummy layer is deposited over the first work function metal layer. An impurity is introduced into the dummy layer and the first work function metal layer after the dummy layer is deposited. The dummy layer is removed after the impurity is introduced into the dummy layer and the first work function metal layer. The gate trench is filled with a conductive material after the dummy layer is removed.

Abstract: A method for manufacturing a semiconductor structure and a semiconductor structure are provided. The method includes the following steps. A bit line structure is formed on a substrate. Each of the bit lines is provided with an insulation block on a side facing away from the substrate. A shielding portion is formed on a top of the insulation block that faces away from the substrate. A projection area of the shielding portion on the substrate is larger than a projection area of the insulation block on the substrate. An insulation sidewall is formed on a sidewall of the bit line and a sidewall of the insulation block, and a gap extending to the substrate is formed within the insulation sidewall corresponding to the shielding portion.

Abstract: Self-aligned FET devices and associated fabrication methods are disclosed herein. A disclosed process for forming a FET includes forming a first mask, implanting a deep well region in a drift region using the first mask, forming a spacer in contact with the first mask, and implanting a shallow well region in the drift region using the first mask and the spacer. A disclosed FET includes a drift region, a shallow well region, a deep well region located between the shallow well region and the drift region, and a junction field effect region: in contact with the shallow well region, the drift region, and the deep well region; and having a junction field effect doping concentration of the first conductivity type. The FETs can include a hybrid channel formed by a portion of the junction field effect region, as influenced by the deep well region, and the shallow well region.

Abstract: A method for making light emitting device LED arrays includes the steps of providing a plurality of LEDs having a desired configuration (e.g., VLED, FCLED, PLED); attaching the LEDs to a carrier substrate and to a temporary substrate; forming one or more metal layers and one or more insulator layers configured to electrically connect the LEDs to form a desired circuitry; and separating the LEDs along with the layered metal layers and insulator layers that form the desired circuitry from the carrier substrate and the temporary substrate.

Abstract: A semiconductor structure and a method for forming a semiconductor structure are provided. The semiconductor structure includes a substrate; a doped region within the substrate; a pair of source/drain regions extending along a first direction on opposite sides of the doped region; a gate electrode disposed in the doped region, wherein the gate electrode has a plurality of first segments extending in parallel along the first direction; and a protection structure over the substrate and at least partially overlaps the gate electrode.

Abstract: A semiconductor device includes a substrate, a drift layer provided on an upper surface side of the substrate, a base layer provided on the upper surface side of the drift layer, an upper semiconductor layer provided on the upper surface side of the base layer, a first electrode provided on the upper surface of the substrate, a second electrode provided on a rear surface of the substrate, a trench extending to the drift layer from the upper surface of the substrate and a gate electrode provided inside the trench, wherein an inner side surface of the trench has a first surface and a second surface provided below the first surface, the second surface tilts inward of the trench with respect to the first surface, and an intersection point of the first surface and the second surface is provided below the base layer.

Abstract: A transistor includes: gate electrodes and field electrodes, wherein in each case one gate electrode and one field electrode are arranged one above another in a vertical direction in a common trench of a semiconductor body; a gate pad to which the gate electrodes are connected; and a source metallization arranged above the semiconductor body. The field electrodes of a first group include at least one contact section. The at least one contact section is arranged between two sections of a gate electrode arranged in the same trench and is connected to the source metallization. The two sections of the gate electrode are separated from one another in a region of the contact section. At least one of the two sections of the gate electrode arranged in the same trench is electrically connected to a gate electrode arranged in a further trench by way of a gate connecting electrode.

Abstract: In an embodiment, a circuit includes: a transformer defining an inductive footprint within a first layer; a grounded shield bounded by the inductive footprint within a second layer separate from the first layer; and a circuit component bounded by the inductive footprint within a third layer separate from the second layer, wherein: the circuit component is coupled with the transformer through the second layer, and the third layer is separated from the first layer by the second layer.

Abstract: The height of a solid-state imaging element is further reduced as compared to the related art. A solid-state imaging element that is a wafer-level chip size package, including: an optical sensor chip; a protective layer that is stacked on a light receiving surface of the optical sensor chip; and a rewiring layer that is stacked on a surface opposite to the light receiving surface of the optical sensor chip, in which a connection terminal of the rewiring layer is a copper flat pad without a solder ball, an alloy layer of tin and copper is not formed on a front surface of the flat pad, and a thermal expansion coefficient of the protective layer is substantially balanced with a thermal expansion coefficient of the rewiring layer.

Abstract: A preparation method for semiconductor device, comprising: forming a body region (110) in the drift region (100), forming a first doped region (111) and a second doped region (112) in the body region (110); forming a first trench (171) penetrating the first doped region (111) and the body region (110) and extending to the drift region (100); forming an extension region (150) with a conductivity type opposite to that of the drift region (100) and surrounding the bottom wall of the first trench (171); filling the first trench (171) with a dielectric layer (130) formed on the sidewall of the trench, a first conductive structure (141) located at the bottom of the trench and a second conductive structure (142) located at the top of the trench; forming a second trench (172) penetrating the body region (110) and extending into the drift region (100); filling the second trench (172) with a third conductive structure (143) and a dielectric layer (130) formed on the inner wall of the trench.