Abstract: Provided is an image pickup device in which intervals at which well contacts are arranged are different.

Abstract: There is provided a solid-state image pickup device including: a semiconductor substrate; a photodiode formed in the semiconductor substrate; a transistor having a gate electrode part or all of which is embedded in the semiconductor substrate, the transistor being configured to read a signal electric charge from the photodiode via the gate electrode; and an electric charge transfer layer provided between the gate electrode and the photodiode.

Abstract: A solid-state imaging device includes, in a semiconductor substrate, a pixel portion provided with a photoelectric conversion portion, which photoelectrically converts incident light to obtain an electric signal and a peripheral circuit portion disposed on the periphery of the pixel portion, wherein a gate insulating film of aMOS transistor in the peripheral circuit portion is composed of a silicon oxynitride film, a gate insulating film of aMOS transistor in the pixel portion is composed of a silicon oxynitride film, and an oxide film is disposed just above the photoelectric conversion portion in the pixel portion.

Abstract: Among other things, one or more support structures for integrated circuitry and techniques for forming such support structures are provided. A support structure comprises one or more trench structures, such as a first trench structure and a second trench structure formed around a periphery of integrated circuitry. In some embodiments, one or more trench structures are formed according to partial substrate etching, such that respective trench structures are formed into a region of a substrate. In some embodiments, one or more trench structures are formed according to discontinued substrate etching, such that respective trench structures comprise one or more trench portions separated by separation regions of the substrate. The support structure mitigates stress energy from reaching the integrated circuitry, and facilitates process-induced charge release from the integrated circuitry.

Abstract: An object is to provide an imaging device in which a circuit for reading a signal is provided in a pixel region. The imaging device includes a first pixel and a second pixel. The first pixel is capable of outputting a first signal output from a pixel circuit included in the first pixel or a second signal input from the first pixel in the previous stage, to the first pixel or the second pixel in the next stage. The second pixel is capable of outputting, to the outside, the first signal or the second signal, which is input from the first pixel in the previous stage, or a third signal output from a pixel circuit included in the second pixel.

Abstract: A semiconductor device according to an embodiment includes a low-adhesion film, a pair of substrates, and a metal electrode. The low-adhesion film has lower adhesion to metal than a semiconductor oxide film. The pair of substrates is provided with the low-adhesion film interposed therebetween. The metal electrode passes through the low-adhesion film and connects the pair of substrates, and includes, between the pair of substrates, a part thinner than parts embedded in the pair of substrates. A portion of the metal electrode embedded in one substrate is provided with a gap interposed between the portion and the low-adhesion film on the other substrate.

Abstract: A light sensor comprises a nanostructure connectable to a source electrode and a drain electrode, and light sensitive moiety covalently attached to a surface of the nanostructure. The light sensitive moiety comprises a light sensitive molecule having an absorbance spectrum in a visible range. The light sensitive molecule is selected such that upon irradiation of the light sensor by light having a central wavelength within the absorbance spectrum, the sensitive molecule transfers or extracts an electron to or from the surface of the nanostructure.

Abstract: A more preferable pixel for detecting a focal point may be formed by using a photoelectric converting film. A solid-state image sensor includes a first pixel including a photoelectric converting unit formed of a photoelectric converting film and first and second electrodes which interpose the same from above and below in which at least one of the first and second electrodes is a separated electrode separated for each pixel, and a second pixel including the photoelectric converting unit in which the separated electrode is formed to have a planar size smaller than that of the first pixel and a third electrode extending at least to a boundary of the pixel is formed in a region which is vacant due to a smaller planar size. The present disclosure is applicable to the solid-state image sensor and the like, for example.

Abstract: An image sensor may include visible light detectors and a near-infrared light detector. The near-infrared light detector may contain a material highly sensitive to near-infrared rays, and thus the size of the near-infrared light detector may be reduced.

Abstract: An image-sensor structure is provided. The image-sensor structure includes a substrate having a first surface and a second surface and including a sensing area, a first metal layer formed above the first surface of the substrate and surrounding the sensing area, and a protection layer formed above the first surface of the substrate and overlying the sensing area and a part of the first metal layer to expose an exposed area of the first metal layer. The exposed area includes a first portion having a first width, a second portion having a second width, a third portion having a third width and a fourth portion having a fourth width.

Abstract: Some embodiments of the present disclosure relate to a method in which a functional layer is formed over an upper semiconductor surface of a semiconductor substrate, and a capping layer is formed over the functional layer. A first etchant is used to form a recess through the capping layer and through the functional layer. The recess has a first depth and exposes a portion of the semiconductor substrate there through. A protective layer is formed along a lower surface and inner sidewalls of the recess. A second etchant is used to remove the protective layer from the lower surface of the recess and to extend the recess below the upper semiconductor surface to a second depth to form a deep trench. To prevent etching of the functional layer, the protective layer remains in place along the inner sidewalls of the recess while the second etchant is used.

Abstract: A capsule Quantum Dot (QD) composition, a light-emitting diode, preparation methods and a display apparatus are provided. The capsule QD composition includes a mesoporous material in submicron or micron order, quantum dots (QDs) adsorbed in pores of the mesoporous material, and an encapsulation material for packaging the QDs in the pores of the mesoporous material.

Abstract: An apparatus including a spin to charge conversion node; and a charge to spin conversion node, wherein an input to the spin to charge conversion node produces an output at the charge to spin conversion node. An apparatus including a magnet including an input node and output node, the input node including a capacitor operable to generate magnetic response in the magnet and the output node including at least one spin to charge conversion material. A method including injecting a spin current from a first magnet; converting the spin current into a charge current operable to produce a magnetoelectric interaction with a second magnet; and changing a direction of magnetization of the second magnet in response to the magnetoelectric interaction. A method including injecting a spin current from an input node of a magnet; and converting the spin current into a charge current at an output node of the magnet.

Abstract: A memory device may include a substrate, a first conductive line on the substrate and extending in a first direction, a second conductive line over the first conductive line and extending in a second direction crossing the first direction, a third conductive line over the second conductive line and extending in the first direction, a first memory cell at an intersection of the first conductive line and the second conductive line and including a first selection element layer and a first variable resistance layer, and a second memory cell at an intersection of the second conductive line and the third conductive line and including a second selection element layer and a second variable resistance layer. A first height of the first selection element layer in a third direction perpendicular to the first and second directions is different than a second height of the second selection element layer in the third direction.

Abstract: A method of manufacturing a memory device includes sequentially forming and then etching a preliminary selection device layer, a preliminary middle electrode layer, and a preliminary variable resistance layer on a substrate, thereby forming a selection device, a middle electrode, and a variable resistance layer. At least one of a side portion of the selection device or a side portion of the variable resistance layer is removed so that a first width of the middle electrode in a first direction parallel to a top of the substrate is greater than a second width of the variable resistance layer in the first direction or a third width of the selection device in the first direction. A capping layer is formed on at least one of a side wall of the etched side portion of the selection device or a side wall of the etched side portion of the variable resistance layer.

Abstract: A semiconductor device including a transistor on a main surface side of a semiconductor substrate; and a resistance change element on a back-surface side of the semiconductor substrate, wherein the transistor includes a low-resistance section in the semiconductor substrate, the low-resistance section extending to the back surface of the semiconductor substrate, an insulating film is provided in contact with a back surface of the low-resistance section, the insulating film has an opening facing the low-resistance section, and the resistance change element is connected to the low-resistance section through the opening.

Abstract: Methods of forming a memory device having an array portion including a plurality of array transistors and a periphery region including peripheral circuit transistor structures of the memory device, where an upper surface of the periphery region and an upper surface of the array portion are planar (or nearly planar) after formation of the peripheral circuit transistor structures and a plurality of memory cells (formed over the array transistors). The method includes forming the peripheral circuit transistor structures in the periphery region, forming the plurality of array transistors in the array portion and forming a plurality of memory cells over respective vertical transistors. Structures formed by the method have planar upper surfaces of the periphery and array regions.

Abstract: A variable resistance memory device including a substrate, a first insulation layer disposed on the substrate, first and second conductive lines, and memory units. The first conductive lines are arranged in a first direction on the first insulation layer and extend in a second direction. The second conductive lines are disposed over the first conductive lines, are arranged in the second direction, and extend in the first direction. The memory units are disposed in each area between the first and second conductive lines in a third direction and include a first electrode, a variable resistance pattern, a selection pattern, and a second electrode. The first electrode and the variable resistance pattern include a cross-section having an “L” shape. The variable resistance pattern contacts an upper surface of the first electrode. The second electrode is disposed on the variable resistance pattern. The selection pattern is disposed on the second electrode.

Abstract: A memory device includes a first electrode line layer including a plurality of first electrode lines extending on a substrate in a first direction and being spaced apart from each other, a second electrode line layer including a plurality of second electrode lines extending on the first electrode line layer in a second direction that is different from the first direction and being spaced apart from each other, and a memory cell layer including a plurality of first memory cells located at a plurality of intersections between the plurality of first electrode lines and the plurality of second electrode lines, each first memory cell including a selection device layer, an intermediate electrode and a variable resistance layer that are sequentially stacked. A side surface of the variable resistance layer is perpendicular to a top surface of the substrate or inclined to be gradually wider toward an upper portion of the variable resistance layer.

Abstract: A negative differential resistance (NDR) device for non-volatile memory cells in crossbar arrays is provided. Each non-volatile memory cell is situated at a crosspoint of the array. Each non-volatile memory cell comprises a switching layer in series with an NDR material containing fast diffusive atoms that are electrochemically inactive. The switching layer is positioned between two elec-trodes.

Abstract: A solid state image sensor includes a semiconductor substrate where photoelectric conversion regions for converting light into charges are arranged per pixel planarly arranged; an organic photoelectric conversion film laminated at a light irradiated side of the semiconductor substrate via an insulation film and formed at the regions where the pixels are formed; a lower electrode formed at and in contact with the organic photoelectric conversion film at a semiconductor substrate side; a first upper electrode laminated at a light irradiated side of the organic photoelectric conversion film and formed such that ends of the first upper electrode are substantially conform with ends of the organic photoelectric conversion film when the solid state image sensor is planarly viewed; and a film stress suppressor for suppressing an effect of a film stress on the organic photoelectric conversion film, the film stress being generated on the first upper electrode.

Abstract: Provided is a manufacturing method of a display device, which includes: forming a first electrode; forming a first insulating film covering an edge portion of the first electrode and having an opening portion overlapping with the first electrode; forming an EL layer over the first electrode and the first insulating film; forming a second electrode over the EL layer; forming a second insulating film over the second electrode so as to overlap with the first insulating film; removing the second insulating film; and forming a sealing film over the second electrode.

Abstract: A foldable, flexible display apparatus includes a flexible display panel which displays an image and includes a display side on which the image is displayed and of which portions thereof face each other in a folded state of the flexible display apparatus; a cover window on the display side of the flexible display panel and including: a window film comprising a transparent plastic film having a modulus of elasticity of about 6.3 gigapascals or more; and a coating layer on the window film, and configured to be transparent and to protect the window film from physical damage thereto; and an adhesive layer between the window film and the display side of the flexible display panel, and configured to have elasticity and bond the window film and the flexible display panel to each other.

Abstract: An organic light-emitting diode (OLED) array substrate, a display device and a manufacturing method thereof are disclosed. The array substrate includes: a substrate and pixel units disposed on the substrate. Each pixel unit includes a plurality of subpixel units; each subpixel unit includes a composite electrode, an organic material functional layer and a first electrode sequentially disposed on the substrate; thicknesses of the composite electrodes of different subpixel units are different; and the composite electrode, the organic material functional layer and the first electrode in a same subpixel unit constitute a microcavity structure.

Abstract: Provided is an organic light emitting diode including a first electrode layer, a second electrode layer opposing the first electrode layer, a first light emitting layer between the first and second electrode layers to generate a first light having a first wavelength, a second light emitting layer between the first light emitting layer and the second electrode layer to generate a second light having a second wavelength which is longer than the first wavelength, and a charge generating layer between the first and second light emitting layers. The first and second lights are emitted through the second electrode layer. An optical length between the first and second electrode layers is substantially the same as a fourth resonant distance of the first light.

Abstract: Provided is an organic EL display panel including pixels that are arranged in a matrix. Each of the pixels includes a plurality of unit pixels. Each of the pixels includes a red unit pixel and a blue unit pixel. The red unit pixel and the blue unit pixel are arranged side by side in a row direction. In pixels adjacent to each other in the row direction among the pixels, unit pixels are arranged in at least one of manners as follows: red unit pixels are adjacent to each other; and blue unit pixels are adjacent to each other.

Abstract: An organic light emitting device utilizing the micro-cavity effect in the RGB subpixel regions while suppressing the micro-cavity effect in the white subpixel region is provided. The organic light emitting device includes a lower substrate, an anode formed on the lower substrate, an organic emission layer formed on the anode, a cathode formed on the organic emission layer, and a reflection decreasing layer formed on at least a portion of the cathode for reducing reflection of the light emitted from the organic emission layer by the cathode to reduce the micro-cavity effect. Such a selective use of the micro-cavity effect in the organic light emitting device improves the color accuracy, the luminance efficiency and the lifespan of the top emission type organic light emitting device.

Abstract: A light emitting element including at least a first trench portion having an indented shape within a single light emitting region. The first trench portion includes a first electrode, an EL layer, and a second electrode. The first electrode, the EL layer, and the second electrode are layered in this order and in contact with each other. At least one of the first electrode or the second electrode includes a reflective electrode.

Abstract: A manufacturing method of a display device including a pixel region including a plurality of pixels each including a light emitting element and a terminal region provided outside the pixel region and including connection terminals; the method comprising: forming a recessed portion in a part of a top surface of each of the connection terminals; forming a first inorganic insulating layer, an organic insulating layer, and a second inorganic insulating layer sequentially in the pixel region and continuously in the terminal region; and etching the first inorganic insulating layer and the second inorganic insulating layer in an area where the first inorganic insulating layer and the second inorganic insulating layer are stacked directly, the area being on the top surface except the recessed portion.

Abstract: A semiconductor device includes as a resistance element a first polycrystalline silicon and a second polycrystalline silicon containing impurities, such as boron, of the same kind and having different widths. The first polycrystalline silicon contains the impurities at a concentration CX. The second polycrystalline silicon has a width larger than a width of the first polycrystalline silicon and contains the impurities of the same kind at a concentration CY lower than the concentration CX. A sign of a temperature coefficient of resistance (TCR) of the first polycrystalline silicon changes at the concentration CX. A sign of a TCR of the second polycrystalline silicon changes at the concentration CY.

Abstract: In one embodiment, a method of manufacturing a silicon-carbide (SiC) device includes receiving a selection of a specific terrestrial cosmic ray (TCR) rating at a specific applied voltage, determining a breakdown voltage for the SiC device based at least on the specific TCR rating at the specific applied voltage, determining drift layer design parameters based at least on the breakdown voltage. The drift layer design parameters include doping concentration and thickness of the drift layer. The method also includes fabricating the SiC device having a drift layer with the determined drift layer design parameters. The SiC device has the specific TCR rating at the specific applied voltage.

Abstract: A semiconductor die includes a substrate and a semiconductor body supported by the substrate and having a periphery which is devoid of active devices and terminates at an edge face of the semiconductor die. The semiconductor body includes a first III-nitride semiconductor layer and a plurality of second III-nitride semiconductor layers below the first III-nitride semiconductor layer. An uninsulated connection structure extends vertically in the periphery of the semiconductor body and provides a vertical leakage path for at least some of the second III-nitride semiconductor layers to the substrate, to a metallization layer disposed above the substrate, or to both. A corresponding method of manufacturing the semiconductor die is also described.

Abstract: We disclose a high voltage semiconductor device comprising a semiconductor substrate of a second conductivity type; a semiconductor drift region of the second conductivity type disposed over the semiconductor substrate, the semiconductor substrate region having higher doping concentration than the drift region; a semiconductor region of a first conductivity type, opposite to the second conductivity type, formed on the surface of the device and within the semiconductor drift region, the semiconductor region having higher doping concentration than the drift region; and a lateral extension of the first conductivity type extending laterally from the semiconductor region into the drift region, the lateral extension being spaced from a surface of the device.

Abstract: A method of manufacturing semiconductor devices in a semiconductor wafer comprises forming charge compensation device structures in the semiconductor wafer. An electric characteristic related to the charge compensation device structures is measured. At least one of proton irradiation and annealing parameters are adjusted based on the measured electric characteristic. The semiconductor wafer is irradiated with protons and annealed based on the at least one of the adjusted proton irradiation and annealing parameters. Laser beam irradiation parameters are adjusted with respect to different positions on the semiconductor wafer based on the measured electric characteristic. The semiconductor wafer is irradiated with a photon beam at the different positions on the wafer based on the photon beam irradiation parameters.

Abstract: A high-performance HBT that is unlikely to decrease the process controllability and to increase the manufacturing cost is implemented. A heterojunction bipolar transistor includes an emitter layer, a base layer, and a collector layer on a GaAs substrate. The emitter layer is formed of InGaP. The base layer is formed of GaAsPBi having a composition that substantially lattice-matches GaAs.

Abstract: A method for forming a semiconductor device includes incorporating dopants of a first conductivity type into a nearby body region portion of a semiconductor substrate having a base doping of the first conductivity type. The incorporation of the dopants of the first conductivity type is masked by a mask structure at at least part of an edge region of the semiconductor substrate. The method further includes forming a body region of a transistor structure of a second conductivity type in the semiconductor substrate. The nearby body region portion of the semiconductor substrate is located adjacent to the body region of the transistor structure.

Abstract: FinFETs and methods of forming finFETs are described. According to some embodiments, a structure includes a channel region, first and second source/drain regions, a dielectric layer, and a gate electrode. The channel region includes semiconductor layers above a substrate. Each of the semiconductor layers is separated from neighboring ones of the semiconductor layers, and each of the semiconductor layers has first and second sidewalls. The first and second sidewalls are aligned along a first and second plane, respectively, extending perpendicularly to the substrate. The first and second source/drain regions are disposed on opposite sides of the channel region. The semiconductor layers extend from the first source/drain region to the second source/drain region. The dielectric layer contacts the first and second sidewalls of the semiconductor layers, and the dielectric layer extends into a region between the first plane and the second plane. The gate electrode is over the dielectric layer.

Abstract: A semiconductor device includes an active pattern provided on a substrate and a gate electrode crossing over the active pattern. The active pattern includes a first buffer pattern on the substrate, a channel pattern on the first buffer pattern, a doped pattern between the first buffer pattern and the channel pattern, and a second buffer pattern between the doped pattern and the channel pattern. The doped pattern includes graphene injected with an impurity.

Abstract: Embodiments of the disclosure generally provide methods of forming thin film transistor (TFT) device structure with good interface management between a metal electrode layer and a nearby insulating material so as to provide high electrical performance devices, or for other suitable display applications. In one embodiment, a thin film transistor structure includes a metal electrode layer disposed on a barrier layer formed above a gate insulating material layer, an interface layer disposed on the metal electrode layer, wherein the interface layer is an oxygen free dielectric material layer sized to be formed predominately on the metal electrode layer, and an insulating material layer disposed on the interface layer, wherein the insulating material layer is an oxygen containing dielectric layer.

Abstract: In a method of manufacturing a semiconductor device, a first fin structure for an n-channel fin field effect transistor (FinFET) is formed over a substrate. An isolation insulating layer is formed over the substrate such that an upper portion of the first fin structure protrudes from the isolation insulating layer. A gate structure is formed over a part of the upper portion of the first fin structure. A first source/drain (S/D) epitaxial layer is formed over the first fin structure not covered by the gate structure. A cap epitaxial layer is formed over the first S/D epitaxial layer. The first S/D epitaxial layer includes SiP, and the cap epitaxial layer includes SiC with a carbon concentration is in a range from 0.5 atomic % to 5 atomic %.

Abstract: In a semiconductor memory device, first insulating films are arranged along a first direction and a second direction and extend in a third direction. Interconnect is disposed between the first insulating films in the first direction and extends in the third direction. Electrodes are disposed between the first insulating films in the first direction on a second direction side of the interconnect, and is arranged along the third direction. Second insulating film is disposed between the interconnect and the electrodes. Semiconductor members are arranged along the third direction between the first insulating films in the second direction and extend in the first direction. The electrode is disposed between the interconnect and the semiconductor members. Third insulating film is disposed between the electrodes and the semiconductor member and is thicker than the second insulating film.

Abstract: Semiconductor structures are provided. The semiconductor structure includes a substrate and a floating gate structure formed over the substrate. The semiconductor structure further includes a dielectric structure formed over the floating gate structure and a control gate structure formed over the dielectric structure. The semiconductor structure further includes a first spacer formed over a lower portion of a sidewall of the control gate structure and an upper spacer formed over an upper portion of the sidewall of the control gate structure. In addition, a portion of the control gate structure is in direct contact with the upper spacer.

Abstract: Source/drain contact structures that exhibit low contact resistance and improved electromigration properties are provided. After forming a first contact conductor portion comprising a metal having a high resistance to electromigration such as tungsten at a bottom portion of source/drain contact trench to form direct contact with a source/drain region of a field effect transistor, a second contact conductor portion comprising a highly conductive metal such as copper or a copper alloy is formed over the first contact conductor portion.

Abstract: A method for manufacturing a silicon carbide semiconductor device includes preparing a silicon carbide layer including an n-type region having an n conductivity type and a p-type region having a p conductivity type, forming a material layer containing titanium, aluminum, and silicon on the n-type region and the p-type region, and forming an electrode layer in contact with the n-type region and the p-type region by heating the material layer. In forming a material layer, composition of the material layer is determined such that a point (x, y, z) (x, y, and z each being a numeric value greater than 0) representing a composition ratio among titanium, aluminum, and silicon is included in a first triangular pyramidal region having four points of the origin (0, 0, 0), a point (1, 2, 2), a point (2, 1, 2) and a point (2, 2, 1) as vertices.

Abstract: An LCD panel, an array substrate and a manufacturing method for TFT are disclosed. The method includes: providing a substrate; forming a first metal layer on the substrate, in which the first metal layer includes an aluminum metal layer, an aluminum oxide layer and a molybdenum metal layer stacked sequentially; patterning the first metal layer to form a gate electrode of a TFT; sequentially forming a gate insulation layer, a semiconductor layer and an ohmic contact layer on the gate electrode; forming a second metal layer on the ohmic contact layer; and patterning the second metal layer to form a source electrode and a drain electrode of the TFT. Hillock generated by the aluminum metal layer in a high temperature environment can be inhibited so as to avoid short-circuiting generated among the gate, the source and the drain electrodes of the TFT to ensure the display quality of an image.

Abstract: A method of fabricating a transistor with reduced hot carrier injection effects includes providing a substrate covered by a gate material layer. Later, the gate material layer is patterned into a gate electrode. Then, a mask layer is formed to cover part of the gate electrode and expose two ends of the gate electrode. Finally, a first implantation process is performed to implant dopants through the exposed two ends of the gate electrode into the substrate directly under the gate electrode to form two LDD regions by taking the mask layer as a mask.

Abstract: Provided are a power device having an improved field stop layer and a method of manufacturing the same. The method can include performing a first ion implant process by implanting impurity ions of a first conductive type into a front surface of a semiconductor substrate to form an implanted field stop layer where the semiconductor substrate is the first conductive type. The method can include performing a second ion implant process by implanting impurity ions of the first conductive type into a first part of the implanted field stop layer such that an impurity concentration of the first part of the implanted field stop layer is higher than an impurity concentration of a second part of the implanted field stop layer.

Abstract: A semiconductor device and a method for manufacturing the same are provided in the present invention. The semiconductor device includes a substrate, agate structure on the substrate and two spacers on both sidewalls of the gate structure. Each spacer comprises an inner first spacer portion made of SiCN and an outer second spacer portion made of SiOCN.

Abstract: Aspects of the present invention relate to a method for manufacturing a high-performance and low-power field effect transistor (FET) element of which surface roughness scattering is minimized or removed, comprising: a first step of etching a strained silicon substrate into a pin structure; a second step of stacking undoped SiGe thereon; a third step of etching the undoped SiGe; a fourth step of etching after performing lithography; a fifth step of stacking doped SiGe thereon; a sixth step of etching the doped SiGe after performing lithography; and a step of forming a transistor element by sequentially stacking an oxide and a gate metal on the doped SiGe and there is an effect of enabling the implementation of a Fin HEMT capable of having all of good channel controllability and a high on-current, which are advantages of a FinFET, and high electron mobility, which is an advantage of an HEMT.

Abstract: A method of forming a FinFET device includes following steps. First of all, a fin shaped structure is formed on a substrate. Then, a portion of the fin shaped structure is removed to form a first trench in the fin shaped structure. Next, a cover film is formed to partially cover surfaces of the first trench and to expose a portion of the fin shaped structure. Afterward, the exposed portion of the fin shaped structure is further removed to form a second trench under the first trench. Finally, a barrier layer is formed on surfaces of the second trench, thereby improving the current leakage issues.