Abstract: A method of producing a semiconductor layer sequence includes providing a growth substrate having a growth surface on a growth side, growing a first nitride semiconductor layer on the growth side, growing a second nitride semiconductor layer on the first nitride semiconductor layer, wherein the second nitride semiconductor layer includes at least one opening or at least one opening is produced in the second nitride semiconductor layer or at least one opening is created in the second nitride semiconductor layer during the growing process, removing at least one part of the first nitride semiconductor layer through the openings in the second nitride semiconductor layer, and growing a third nitride semiconductor layer on the second nitride semiconductor layer, wherein the third nitride semiconductor layer covers the openings at least in places.

Abstract: A semiconductor device including: a fuse element; and a fuse window that is formed above a region including the fuse element, that includes a pair of first sidewalls extending in a first direction running along a direction that current flows in the fuse element and a pair of second sidewalls extending in a second direction intersecting the first direction, and that is formed with a projection projecting out from a sidewall side toward the inside at an inner wall of at least one out of the first sidewalls or the second sidewalls, the projection having a sidewall side width that is narrower than a projecting side width.

Abstract: A semiconductor device includes an isolation layer, first and second fin structures, a gate structure and a source/drain structure. The isolation layer is disposed over a substrate. The first and second fin structures are disposed over the substrate, and extend in a first direction in plan view. Upper portions of the first and second fin structures are exposed from the isolation layer. The gate structure is disposed over parts of the first and second fin structures, and extends in a second direction crossing the first direction. The source/drain structure is formed on the upper portions of the first and second fin structures, which are not covered by the first gate structure and exposed from the isolation layer, and wraps side surfaces and a top surface of each of the exposed first and second fin structures. A void is formed between the source/drain structure and the isolation layer.

Abstract: The present disclosure may provide a semiconductor device with an enhanced integration. The device may include a lower pipe gate; an upper pipe gate including a first horizontal portion and first and second protrusions, the first horizontal portion being parallel to the lower pipe gate, the first and second protrusions extending from the first horizontal portion to the lower pipe gate and crossing each other so as to define a pipe channel region; a partition pipe gate disposed between the lower and upper pipe gates, the partition pipe gate dividing the pipe channel region into first and second pipe channel regions; and first and second pipe channel films disposed respectively in the first and second pipe channel regions.

Abstract: A semiconductor package is provided, including: an insulating base body having a first surface with an opening and a second surface opposite to the first surface; an insulating extending body extending outward from an edge of the first surface of the insulating base body, wherein the insulating extending body is less in thickness than the insulating base body; an electronic element having opposite active and inactive surfaces and disposed in the opening with its inactive surface facing the insulating base body; a dielectric layer formed in the opening of the insulating base body and on the first surface of the insulating base body, the insulating extending body and the active surface of the electronic element; and a circuit layer formed on the dielectric layer and electrically connected to the electronic element. The configuration of the insulating layer of the invention facilitates to enhance the overall structural rigidity of the package.

Abstract: Provided are a semiconductor device manufacturing method and semiconductor device such that manufacturing can be simplified and the thickness of the semiconductor device can be reduced. The semiconductor device includes an insulated circuit substrate having on one main surface thereof a first metal layer and a second metal layer, a metal plate conductively connected to the first metal layer, a first semiconductor element including on front and rear surfaces thereof a plurality of metal electrodes, a first insulating member disposed on a side surface of the first semiconductor element, a second insulating member disposed on the first insulating member and on the first semiconductor element, and a third metal layer, in which at least one portion thereof is disposed on the second insulating member and which conductively connects the metal electrode of the first semiconductor element and the second metal layer on the insulated circuit substrate.

Abstract: A single-layer wiring package substrate and a method of fabricating the same are provided, the method including: forming on a carrier a wiring layer having a first surface and a second surface opposing the first surface and being in contact with the carrier; forming on the carrier and on the wiring layer a dielectric body that has a first side having a first opening, from which a portion of the wiring layer is exposed, and a second side opposing the first side and disposed at the same side as the second surface of the wiring layer; and removing the carrier, with the second side of the dielectric body and the second surface of the wiring layer exposed. Therefore, a coreless package substrate is fabricated, and the overall thickness and cost of the substrate are reduced.

Abstract: A semiconductor device including a fin active region protruding from a substrate and an isolation region defining the fin active region, a gate pattern intersecting the fin active region and the isolation region, and gate spacer formed on a side surface of the gate pattern and extending onto a surface of the isolation region is provided.

Abstract: A strip of semiconductor devices includes a plurality of leadframes electrically isolated from each other, a plurality of semiconductor chips, and an encapsulation material. Each leadframe has a first surface and a second surface opposite to the first surface. At least one semiconductor chip of the plurality of semiconductor chips is electrically coupled to the first surface of each leadframe. The encapsulation material encapsulates each semiconductor chip and at least portions of each leadframe.

Abstract: Methods of forming microelectronic interconnect under device structures are described. Those methods and structures may include forming a device layer in a first substrate, forming at least one routing layer in a second substrate, and then coupling the first substrate with the second substrate, wherein the first substrate is bonded to the second substrate.

Abstract: An electronic module includes a circuit board, having a carrier layer, the carrier layer having a plurality of recess areas in a main surface thereof, and a plurality of electronic sub-modules, each one of the sub-modules being disposed in one of the recess areas and each one of the sub-modules having a carrier, a semiconductor chip disposed on the carrier, and an encapsulation material disposed on the carrier and on the semiconductor chip.

Abstract: A film is efficiently formed by sufficiently supplying a source gas to substrates accommodated in a process chamber, and the uniformity of a film formed on the substrates is improved. A method of a semiconductor device manufacturing includes (a) supplying a source gas to an upper region of a process chamber through a first gas supply hole disposed at a front end of a first nozzle disposed in a lower region of the process chamber where the source gas is not pyrolyzed; (b) supplying the source gas to substrates disposed in the lower region and a middle region of the process chamber through a plurality of second gas supply holes of a second nozzle; and (c) supplying a reactive gas to substrates disposed in the lower region, the middle region and the upper region of the process chamber through a plurality of third gas supply holes of a third nozzle.

Abstract: When upper surfaces of a control gate electrode and a memory gate electrode are exposed from an interlayer insulating film by polishing the interlayer insulating film in a gate last process, a silicide layer covering the upper surfaces of the gate electrodes is formed. Thereafter, by reacting a metal film deposited on the silicide layer with the control gate electrode and the memory gate electrode, a silicide layer thicker than the former silicide layer is formed on each of the gate electrodes.

Abstract: A method of producing an organic EL device includes forming an organic EL element including a pixel electrode, a functional layer, and a counter electrode over a substrate, forming a cathode protective layer over the organic EL element, forming a cover layer over the cathode protective layer, forming an organic buffer layer over the cover layer, and forming a gas barrier layer over the organic buffer layer.

Abstract: According to the embodiments, a semiconductor device includes a substrate, a plurality of insulating layers, a lower shield plate, a semiconductor device, an upper shield plate, and a side shield member. A first contact portion is formed on the substrate. The lower shield plate includes a magnetic substance and is provided above the substrate so as to avoid the first contact portion. The semiconductor chip is provided above the lower shield plate and has a second contact portion electrically connected to the first contact portion. The upper shield plate includes a magnetic substance and is provided above the semiconductor chip so as to avoid the second contact portion and a connection member. The side shield member includes a magnetic substance and connects side portions of the lower shield plate and the upper shield plate on which the connection member is not disposed.

Abstract: In a general aspect, a packaged semiconductor device can include a semiconductor die having at least a first terminal on a first side of the semiconductor die and a second terminal on a second side of the semiconductor die. The device can include a leadframe portion electrically coupled to the first terminal of the semiconductor die and a clip portion electrically coupled to the second terminal of the semiconductor die. The device can include a molding compound. A surface of the leadframe portion and a first surface of the molding compound can define at least a portion of a first surface of the device. A surface of the clip portion and a second surface of the molding compound can define at least a portion of a second surface of the device that is parallel to the first surface of the device.

Abstract: In one embodiment, a bi-directional punch-through semiconductor device can include: a first transistor in a first region of a semiconductor substrate of a first conductivity type, where the first transistor includes a semiconductor buried layer of a second conductivity type in the semiconductor substrate, and a first epitaxy region of an epitaxy semiconductor layer above the semiconductor buried layer, the semiconductor buried layer being configured as a base of the first transistor; and a second transistor coupled in parallel with the first transistor, where the second transistor is in a second region of the semiconductor substrate of the first conductivity type, where the second transistor comprises a second epitaxy region of the epitaxy semiconductor layer above the semiconductor substrate, and a first doped region of the second conductivity type in the second epitaxy region, the first doped region being configured as a base of the second transistor.

Abstract: An integrated circuit comprises standard cells arranged in rows and columns. The integrated circuit also comprises tap cells arranged in rows and columns. The tap cells each comprise a substrate having a first dopant type and a thickness from a first surface of the substrate to a second surface of the substrate. The integrated circuit further comprises a well region in the substrate having a second dopant type different from the first dopant type and a depth from the first surface of the substrate less than the thickness of the substrate. The integrated circuit additionally comprises a first quantity of rows of tap cells and a second quantity of rows of tap cells less than the first quantity. Each row of the first quantity of rows of tap cells comprises at least one well contact, and each row of tap cells of the second quantity of tap cells comprises at least one substrate contact.

Abstract: Semiconductor devices and methods of manufacturing the semiconductor devices are provided. The semiconductor devices may include a first line pattern that includes a first main line having a first width and a first subline having a second width, and a second line pattern that includes a second main line having the first width and a second subline having a third width. The first line pattern may include a first width changer whose width increases from the first width to the second width. The second line pattern may include a second width changer whose width increases from the first width to the third width.

Abstract: Magnetoresistive random access memory (MRAM) devices include a first magnetic layer. A tunnel barrier layer is formed on the first magnetic layer. The tunnel barrier includes first regions having a first thickness and second regions having a second thickness that is greater than the first thickness. A second magnetic layer is formed on the tunnel barrier layer.