Abstract: Embodiments of a method for fabricating System-in-Packages (SiPs) are provided, as are embodiments of a SiP. In one embodiment, the method includes producing a first package including a first molded package body having a sidewall. A first leadframe is embedded within the first molded package body and having a first leadframe lead exposed through the sidewall. In certain implementations, a semiconductor die may also be encapsulated within the first molded package body. A Surface Mount Device (SMD) is mounted to the sidewall of the first molded package body such that a first terminal of the SMD is in ohmic contact with the first leadframe lead exposed through the sidewall.

Abstract: The invention relates to transferring, in one exposure, a single-mask feature to form two features on an underlying material. Specifically, a doubled walled structure (i.e. a center opening flanked by adjacent openings) is formed. Advantageously, the openings may be sub-resolution openings. The center opening may be a line flanked by two other lines. The center opening may be circular and surrounded by an outer ring, thus forming a double wall ring structure. In an electronic fuse embodiment, the double wall ring structure is a via filled with a conductor that contacts a lower and upper level metal. In deep trench embodiment, the double wall ring structure is a deep trench in a semiconductor substrate filled with insulating material. In such a way the surface area of the trench is increased thereby increasing capacitance.

Abstract: A semiconductor device includes: an FET structure that is formed next to a looped trench on a semiconductor substrate and that has an n+ emitter region and an n? drain region facing each other in the depth direction of the looped trench across a p-type base region; a p-type floating region formed on the side of the looped trench opposite to the FET structure; and an emitter connecting part that is electrically connected to the n+ emitter region and a trench gate provided in the same trench, the emitter connecting part and the trench gate being insulated from each other by the looped trench. The trench gate faces the FET structure, and the emitter connecting part faces the p-type floating region, across an insulating film.

Abstract: The subject matter disclosed herein relates to silicon carbide (SiC) power devices and, more specifically, to active area designs for SiC super-junction (SJ) power devices. A SiC-SJ device includes an active area having one or more charge balance (CB) layers. Each CB layer includes a semiconductor layer having a first conductivity-type and a plurality of floating regions having a second conductivity-type disposed in a surface of the semiconductor layer. The plurality of floating regions and the semiconductor layer are both configured to substantially deplete to provide substantially equal amounts of charge from ionized dopants when a reverse bias is applied to the SiC-SJ device.

Abstract: In one general aspect, an apparatus can include a junction-less, gate-controlled voltage clamp device having a gate terminal coupled to a voltage reference device.

Abstract: The invention bears on elementary nanoscale units nanostructured-formed inside a silicon material and the manufacturing process to implement them. Each elementary nanoscale unit is created by means of a limited displacement of two Si atoms outside a crystal elementary unit. A localized nanoscale transformation of the crystalline matter gets an unusual functionality by focusing in it a specific physical effect as is a highly useful additional set of electron energy levels that is optimized for the solar spectrum conversion to electricity. An adjusted energy set allows a low-energy secondary electron generation in a semiconductor, preferentially silicon, material for use especially in very-high efficiency all-silicon light-to-electricity converters. The manufacturing process to create such transformations in a semiconductor material bases on a local energy deposition like ion implantation or electron (?,X) beam irradiation and suitable thermal treatment and is industrially easily available.

Abstract: An LED die includes a substrate, a pre-growth layer, a first insulating layer and a light emitting structure. The pre-growth layer, the first insulating layer and the light emitting structure are formed on the structure that order. The substrate includes a first electrode, a second electrode and an insulating part. The insulating part is formed between the first electrode and the second electrode. The LED die further includes a second insulating layer and a metal layer which are formed around the pre-growth layer. The present disclosure includes a method for manufacturing the LED die.

Abstract: When VC inspection for a TEG is performed, it is easily detected whether any failure of a contact plug occurs or not by increasing an emission intensity of a contact plug, so that reliability of a semiconductor device is improved. An element structure of an SRAM is formed on an SOI substrate in a chip region. Also, in a TEG region, an element structure of an SRAM in which a contact plug is connected to a semiconductor substrate is formed on the semiconductor substrate exposed from an SOI layer and a BOX film as a TEG used for the VC inspection.

Abstract: A semiconductor device includes a transistor and a contact pad over a substrate. The transistor includes a high-k dielectric layer, a work function metal layer, a metal gate, two spacers, a metal compound, an insulator and a doped region. The high-k dielectric layer is over the substrate. The work function metal layer is over the high-k dielectric layer. The metal gate is over the work function metal layer. The two spacers sandwich the work function metal layer and the metal gate. The metal compound is over inner walls of the two spacers and over the top surface of the work function metal layer and the metal gate. The insulator covers the metal compound. The doped region is in the substrate. The contact pad is electrically connected to the metal gate.

Abstract: An optoelectronic semiconductor chip includes a semiconductor body that has a semiconductor layer sequence and at least one opening that extends through a second semiconductor layer into a first semiconductor layer. The chip also includes a support, which includes at least one recess, and a metallic connecting layer between the semiconductor body and the support. The metallic connecting layer includes a first region and a second region. The first region is connected to the first semiconductor layer in an electrically conductive manner through the opening and the second region is connected to the second semiconductor layer in an electrically conductive manner. A first contact is connected to the first region in an electrically conductive manner through the recess or a second contact is connected to the second region in an electrically conductive manner through the recess.

Abstract: A semiconductor device includes a substrate, first electronic circuitry formed on the substrate, a first diode buried in the substrate under the first electronic circuitry, and a first fault detection circuit coupled to the first diode to detect energetic particle strikes on the first electronic circuitry.

Abstract: A method of fabricating non-tilted, electrically isolated fins from a bulk substrate is provided. A plurality of semiconductor fins is formed extending upwards from a remaining portion of a bulk semiconductor substrate. Each semiconductor fin includes a hard mask cap. A sacrificial dielectric material portion is formed between each semiconductor fin, wherein each sacrificial dielectric material portion has a topmost surface that is vertically offset and located below a topmost surface of each hard mask cap. An anchoring structure having an opening is then formed atop each sacrificial dielectric material portion and each hard mask cap. Next, an entirety of each sacrificial dielectric material portion is removed by etching through the opening. An oxide layer is then formed within an upper portion of the remaining portion of the bulk semiconductor substrate, wherein a portion of the oxide layer extends beneath each semiconductor fin. Next, the anchoring structure is removed.

Abstract: According to example embodiments, a semiconductor device and a method for manufacturing the same are provided, the semiconductor device includes a substrate including a PMOSFET region and an NMOSFET region, a first gate electrode and a second gate electrode on the PMOSFET region, a third gate electrode and a fourth gate electrode on the NMOSFET region, and a first contact and a second contact connected to the first gate electrode and the fourth gate electrode, respectively. The first to fourth gate cut electrodes define a gate cut region that passes between the first and third gate electrodes and between the second and fourth gate electrodes. A portion of each of the first and second contacts overlaps with the gate cut region when viewed from a plan view.

Abstract: A system and method for a multi-sensor pixel architecture for use in a digital imaging system is described. The system includes at least one semiconducting layer for absorbing radiation incident on opposites of the at least one semiconducting layer along with a set of electrodes on one side of the semiconducting layer for transmitting a signal associated with the radiation absorbed by the semiconducting layer.

Abstract: A method of forming a finFET device comprises forming a fin in a silicon layer of a substrate, forming a hardmask layer on a top surface of the fin, forming an insulating layer over the fin and the hardmask layer, removing a portion of the insulating layer to expose a portion of the hardmask layer, removing the exposed portion of the hardmask layer to form a cavity that exposes a portion of the silicon layer of the fin, epitaxially growing a silicon germanium (SiGe) material on exposed portions of the silicon layer of the fin in the cavity, and annealing the grown SiGe to drive germanium atoms into the silicon layer of the fin.

Abstract: A method for the selective implantation of a workpiece is disclosed. In place of conventional photoresist, a two layer structure is used. The first layer, referred to as the protective layer, is applied directly to the workpiece and protects the workpiece from harmful etching processes. Additionally, the protective layer has limited ability to stop ions from impacting the workpiece. The second layer, referred to as the blocking layer, which is formed on a portion of the protective layer, is used to block ions from impacting the underlying workpiece. Advantageously, the blocking layer may be selectively etched without affecting the protective layer. Additionally, the protective layer can be removed without affecting the underlying workpiece. Through the use of this two layer technique, high temperature selective implants may be performed on a variety of different semiconductor devices.

Abstract: The present invention concerns a plating method for manufacturing of electrical contacts on a solar module wherein the wiring between silicon solar cells in a solar module is deposited by electroplating onto a conductive seed. The wiring between individual silicon solar cells comprises wiring reinforcement pillars which improve the reliability of said wiring.

Abstract: According to an embodiment, a micro-fabricated test structure includes a structure mechanically coupled between two rigid anchors and disposed above a substrate. The structure is released from the substrate and includes a test layer mechanically coupled between the two rigid anchors. The test layer includes a first region having a first cross-sectional area and a constricted region having a second cross-sectional area smaller than the first cross-sectional area. The structure also includes a first tensile stressed layer disposed on a surface of the test layer adjacent the first region.

Abstract: Provided are methods of manufacturing a substrate for an OED and an OED. According to the methods of manufacturing a substrate for forming an OED such as an OLED and an OED, a substrate for forming a device having excellent light extraction efficiency and improved reliability by preventing penetration of moisture or air into the device, or device using the same may be provided.

Abstract: This disclosure relates to an array substrate wiring and manufacturing and repairing method thereof. The array substrate wiring comprises a first wiring formed on the substrate for transmitting electric signals; an insulating layer formed on the first wiring; a second wiring formed on the insulating layer, being opposite to the first wiring, the second wiring being in a hanging state and not transmitting electric signals. By means of such a double layer wiring structure, the holes produced in the insulating layer are blocked using the second wiring in the upper layer, such that the outside moisture cannot reach the first wiring via the holes in the insulating layer, thereby protecting the first wiring for transmitting electric signals from corrosion and scratch.