Abstract: A circuit structure includes a semiconductor substrate having a top surface. A dielectric material extends from the top surface into the semiconductor substrate. A high-k dielectric layer is formed of a high-k dielectric material, wherein the high-k dielectric layer comprises a first portion on a sidewall of the dielectric material, and a second portion underlying the dielectric material.

Abstract: A manufacturing method of the invention, comprising: successively forming an insulation layer and a photoresist layer on a transparent substrate; performing an exposure and a development on the photoresist layer by a back exposure process, so as to form a trench in the photoresist layer, an open area of the trench proximal to the insulation layer is larger than that of the trench distal to the insulation layer; removing a portion of insulation material in a region of the insulation layer exposed through the trench by an etching process, so as to form a slot in the insulation layer; forming a metal layer on a side of the photoresist layer distal to the insulation layer, a portion of the metal layer is embedded in the slot; removing the photoresist layer and the metal layer thereon by a stripping process, and retaining the portion of the metal layer in the slot.

Abstract: The benefits of strained semiconductors are combined with silicon-on-insulator approaches to substrate and device fabrication.

Abstract: According to an embodiment, a microfabricated structure includes a cavity disposed in a substrate, a first clamping layer overlying the substrate, a deflectable membrane overlying the first clamping layer, and a second clamping layer overlying the deflectable membrane. A portion of the second clamping layer overlaps the cavity.

Abstract: Methods for fabricating a semiconductor devices, and in particular light emitting diodes (LEDS) comprising providing a plurality of semiconductor devices on a substrate and forming a contact on at least some of the semiconductor devices. A containment structure is formed on at least some of the semiconductor devices having a contact with each containment structure defining a deposition area excluding the contact. A coating material is deposited then within the deposition area, with the coating material not covering the contact. A light emitting diode (LED) chip wafer comprising a plurality of LEDs on a substrate wafer with at least some of the LEDs having a contact. A plurality of containment structures are included, each of which is associated with a respective one of the plurality of LEDs. Each of the containment structures at least partially on its respective one of the LEDs and defining a deposition area on its respective one of the LEDs. The deposition area excludes the contact.

Abstract: Some embodiments of the present disclosure relate to a method for forming flash memory. In this method, a tunnel oxide is formed over a semiconductor substrate. A layer of silicon dot nucleates is formed on the tunnel oxide. The layer of silicon dots includes silicon dot nucleates having respective initial sizes which differ according to a first size distribution. An etching process is performed to reduce the initial sizes of the silicon dot nucleates so reduced-size silicon dot nucleates have respective reduced sizes which differ according to a second size distribution. The second size distribution has a smaller spread than the first size distribution.

Abstract: First polysilicon (poly-1) is deposited into deep trenches that have been formed in a substrate. A first polysilicon polishing process is performed to planarize the exposed surfaces of the poly-1 so that the surfaces are flush with adjacent surfaces. Then, shallow trenches are formed in the substrate between the deep trenches, and second polysilicon (poly-2) is deposited into the shallow trenches. A second polysilicon polishing process is performed to planarize the exposed surface of the poly-2 so that the surface is flush with adjacent surfaces. Metal contacts to the poly-1 and the poly-2 are then formed.

Abstract: A semiconductor device and methods for making the same are disclosed. The device may include: a first transistor structure; a second transistor structure; a capacitor structure comprising a trench in the substrate between the first and second transistor structures, the capacitor structure further comprising a doped layer over the substrate, a dielectric layer over the doped layer, and a conductive fill material over the dielectric layer; a first conductive contact from the first transistor structure to a first bit line; a second conductive contact from the second transistor to a non-volatile memory element; and a third conductive contact from the non-volatile memory element to a second bit line.

Abstract: A method of fabricating a vertical fin field effect transistor with a strained channel, including, forming a strained vertical fin on a substrate, forming a plurality of gate structures on the strained vertical fin, forming an interlevel dielectric on the strained vertical fin, forming a source/drain contact on the vertical fin adjacent to each of the plurality of gate structures, and selectively removing one or more of the source/drain contacts to form a trench adjacent to a gate structure.

Abstract: A carbon nanotube triode apparatus includes a plurality of Horizontally Aligned Single Wall Carbon Nano Tubes (HA-SWCNT) disposed on an electrically insulating thermally conductive substrate. A first contact is disposed on the substrate and electrically coupled to a first end of the HA-SWCNT. A second contact is disposed on the substrate and separated from a second end of the HA-SWCNT by a gap. A gate terminal is coincident with a plane of the substrate.

Abstract: At least one embodiment is directed to a semiconductor edge termination structure, where the edge termination structure comprises several doped layers and a buffer layer.

Abstract: Provided is a semiconductor device, which prevents unnecessary voltage drop in a MOS transistor that is connected in series in a location between a booster circuit and a memory main body portion, to thereby operate on a low voltage and improve the ON/OFF ratio so that chip size shrinking and memory performance improvement are accomplished simultaneously. In a semiconductor memory device including a memory transistor portion and a select transistor portion, at least the select transistor portion is formed of a fin-shaped single-crystal semiconductor thin film.

Abstract: In accordance with an embodiment, a method of manufacturing an electrical component that may include a high voltage capacitor that includes providing a semiconductor material of a second conductivity type in which first doped region of a first conductivity type is formed. A plurality of doped regions of the first conductivity type and a plurality of doped regions of the second conductivity type are formed in the first doped region. A first p-n junction is formed between first doped regions of the first and second conductivity types and a second p-n junction is formed between second doped regions of the first and second conductivity types. A metallization system is formed above the doped regions so that capacitors are formed by a parallel connection of a first metal layer to a polysilicon layer and the first metal layer to a second metal layer.

Abstract: A method is presented for forming a semiconductor device. The method includes forming source/drain over a semiconductor substrate, forming a sacrificial layer over the source/drain, and forming an inter-level dielectric (ILD) layer over the sacrificial layer. The method further includes forming trenches that extend partially into the sacrificial layer, removing the sacrificial layer to expose an upper surface of the source/drain, and filling the trenches with at least one conducting material. The sacrificial layer is germanium (Ge) and the at least one conducting material includes three conducting materials.

Abstract: The present invention pertains to a group III-V compound semiconductor nanowire able to be used in a group III-V compound semiconductor MOSFET (FET) operational at a small subthreshold (100 mV/dec or less). A side face of the group III-V compound semiconductor nanowire is a (?110) plane constituted of a very small (111) plane. The group III-V compound semiconductor nanowire has, e.g., a first layer having a (111)A plane as a side face thereof, and a second layer having a (111)B plane as a side face thereof. The first layer and the second layer are stacked alternatingly in the axial direction.

Abstract: Embodiments are directed to a method Embodiments are directed to a test structure of a fin-type field effect transistor (FinFET). The test structure includes a first conducting layer electrically coupled to a dummy gate of the FinFET, and a second conducting layer electrically coupled to a substrate of the FinFET. The test structure further includes a third conducting layer electrically coupled to the dummy gate of the FinFET, and a first region of the FinFET at least partially bound by the first conducting layer and the second conducting layer. The test structure further includes a second region of the FinFET at least partially bound by the second conducting layer and the third conducting layer, wherein the first region comprises a first dielectric having a first dimension, and wherein the second region comprises a second dielectric having a second dimension greater than the first dimension.

Abstract: A semiconductor device includes a lower layer, an upper layer on the lower layer, a contact between the lower layer and the upper layer, the contact electrically connects the lower layer and the upper layer, a capping pattern wrapping around the contact and covering an upper surface of the contact, a barrier layer wrapping around the capping pattern and covering a lower surface of the capping pattern and a lower surface of the contact, and an interlayer insulating layer between the lower layer and the upper layer, the interlayer insulating layer wrapping around the barrier layer and exposing an upper surface of the capping pattern, wherein the capping pattern includes a material having an etching selectivity with respect to an oxide.

Abstract: A thin film transistor includes a gate electrode, a insulating medium layer and at least one Schottky diode unit. The at least one Schottky diode unit is located on a surface of the insulating medium layer. The at least one Schottky diode unit includes a first electrode, a semiconductor structure and a second electrode. The semiconductor structure comprising a first end and a second end. The first end is laid on the first electrode, the second end is located on the surface of the insulating medium layer. The semiconducting structure includes a carbon nanotube structure. The second electrode is located on the second end.

Abstract: A thin film transistor includes a gate, an insulating medium layer and a Schottky diode. The Schottky diode includes a first electrode, a second electrode and a semiconducting structure. The first electrode is located on the surface of the insulating medium layer and includes a first metal layer and a second metal layer. The second electrode is located on the surface of the insulating medium layer and includes a third metal layer and a fourth metal layer. The semiconductor structure includes a first end and a second end. The first end is sandwiched by the first metal layer and the second metal layer, the second end is sandwiched by the third metal layer and the fourth metal layer. The semiconductor structure includes a carbon nanotube structure.

Abstract: A thin-film transistor (TFT) array substrate includes a TFT arrangement and a storage capacitor. A gate insulation layer has a portion interposed between two electrode plates of the storage capacitor and thinner than a remaining portion of the gate insulation layer and thus, the thickness of insulation between the electrode plates of the storage capacitor is reduced so that the area of the opposite surfaces of the capacitor can be made smaller and an increased aperture ratio can be achieved.