Abstract: A light emitting device is provided that has a semiconductor light emitting element and a phosphor which converts a part of the luminescence spectrum emitted from the semiconductor light emitting element. The luminescence spectrum of the semiconductor light emitting element is located between a near ultraviolet region and a short-wavelength visible region, and the phosphor is made by adding a red luminescent activator to a base material of a blue luminescent phosphor. Thereby, improving the color shading generated by the dispersion of the spectra of the light emitting elements and obtaining the light emitting device having a high brightness and a good color rendering properties. With the light emitting device, it is possible to provide the light sources for the lighting apparatus of medical treatments, the flash plate of a copying machine, etc., in which a good color rendering property is required.

Abstract: An embodiment of the invention discloses an optoelectronic semiconductor device comprising a semiconductor system capable of performing a conversion between light energy and electrical energy; an interfacial layer formed on at least two surfaces of the semiconductor system; an electrical conductor; and an electrical connector electrically connecting the semiconductor system to the electric conductor.

Abstract: This gallium nitride-based compound semiconductor light emitting device includes an n-type semiconductor layer, a light emitting layer, and a p-type semiconductor layer that are composed of gallium nitride-based compound semiconductors and are deposited in that order on a substrate, and further includes a negative electrode and a positive electrode that are in contact with the n-type semiconductor layer and the p-type semiconductor layer, respectively, wherein the positive electrode has a translucent electrode composed of a three-layer structure including a contact metal layer that contacts at least the p-type semiconductor layer, a current diffusion layer provided on the contact metal layer and having conductivity greater than that of the contact metal layer, and a bonding pad layer provided on the current diffusion layer, and a mixed positive electrode-metal layer including a metal that forms the contact metal layer is present in a positive electrode side surface of the p-type semiconductor layer.

Abstract: A submount comprising a ceramic substrate and a circuitry arranged thereon is provided. The circuitry comprises an electrically conducting porous material comprising at least one noble metal doped with at least one non-noble metal, the surface of at least portions of said electrically conducting porous material comprises oxides of said non-noble metals, and said ceramic substrate is bonded to said porous electrically conducting material via said oxides of said non-noble metals.

Abstract: The present invention discloses a manufacture method for a thin double-sided package substrate, which includes steps: providing a carrier; respectively forming a first conductive layer and a second conductive layer on the upper and lower surfaces of the carrier; forming a through-hole penetrating the first conductive layer and the carrier but not penetrating the second conductive layer; setting a conductive element in the through-hole to electrically connect the first conductive layer with the second conductive layer; forming desired circuits on the first conductive layer and/or the second conductive layer; forming a first metal layer on the first conductive layer and/or the second conductive layer; and removing the carrier located in a predetermined region to form a chip receiving bay.

Abstract: The present disclosure relates to an III-nitride semiconductor light emitting device, particularly, an electrode structure thereof. The III-nitride semiconductor light emitting device includes a substrate, a plurality of III-nitride semiconductor layers grown on the substrate, and composed of a first III-nitride semiconductor layer with first conductivity, a second III-nitride semiconductor layer with second conductivity different from the first conductivity, and an active layer positioned between the first III-nitride semiconductor layer and the second III-nitride semiconductor layer, for generating light by recombination of electrons and holes, and a hole passing through the substrate and the plurality of III-nitride semiconductor layers.

Abstract: A surface mountable device having a circuit device and a base section. The circuit device includes top and bottom layers having a top contact and a bottom contact, respectively. The base section includes a substrate having a top base surface and a bottom base surface. The top base surface includes a top electrode bonded to the bottom contact, and the bottom base surface includes first and second bottom electrodes that are electrically isolated from one another. The top electrode is connected to the first bottom electrode, and the second bottom electrode is connected to the top contact by a vertical conductor. An insulating layer is bonded to a surface of the circuit device and covers a portion of a vertical surface of the bottom layer. The vertical conductor includes a layer of metal bonded to the insulating layer.

Abstract: Exemplary embodiments of the selective laser repair apparatus and method may allow the repair of metal bumps in a semiconductor device stack by applying a laser beam to a damaged and/or defective bump. Metal bumps may be repaired and individual chips and/or packages forming a device stack need not be separated. The operation of a control unit and a driving unit may position a laser unit such that a laser beam may be irradiated at the damaged and/or defective metal bump. An X-ray inspection unit may obtain information about the damaged and/or defective metal bump.

Abstract: A group III nitride semiconductor light-emitting device comprises an n-type gallium nitride-based semiconductor layer, a first p-type AlXGa1-XN (0?X<1) layer, an active layer including an InGaN layer, a second p-type AlYGa1-YN (0?Y?X<1) layer, a third p-type AlZGa1-XN layer (0?Z?Y?X<1), and a p-electrode in contact with the third p-type AlZGa1-ZN layer. The active layer is provided between the n-type gallium nitride-based semiconductor layer and the first p-type AlXGa1-XN layer. The second p-type AlYGa1-YN (0?Y?X<1) layer is provided on the first p-type AlXGa1-XN layer. The p-type dopant concentration of the second p-type AlYGa1-YN layer is greater than the p-type dopant concentration of the first p-type AlXGa1-XN layer. The third p-type AlZGa1-ZN layer (0?Z?Y?X<1) is provided on the second p-type AlYGa1-YN layer. The p-type dopant concentration of the second p-type AlYGa1-YN layer is greater than a p-type dopant concentration of the third p-type AlZGa1-ZN layer.

Abstract: Provided are a light emitting diode (LED) and a method for manufacturing the same. The LED includes an n-type semiconductor layer, an active layer, and a p-type semiconductor layer. The active layer includes a well layer and a barrier layer that are alternately laminated at least twice. The barrier layer has a thickness at least twice larger than a thickness of the well layer.

Abstract: A nitride-based semiconductor substrate has a diameter of 25 mm or more, a thickness of 250 micrometers or more, a n-type carrier concentration of 1.2×1018 cm?3 or more and 3×1019 cm?3 or less, and a thermal conductivity of 1.2 W/cmK or more and 3.5 W/cmK or less. Alternatively, the substrate has an electron mobility ? [cm2/Vs] of more than a value represented by loge?=17.7?0.288 logen and less than a value represented by loge?=18.5?0.288 logen, where the substrate has a n-type carrier concentration n [cm?3] that is 1.2×1018 cm?3 or more and 3×1019 cm?3 or less.

Abstract: A transistor switch circuit includes: a MOS transistor in which a channel is formed when a gate-source voltage is zero; and a voltage supply part which is connected to a gate of the MOS transistor to supply the gate with a voltage for turning off the MOS transistor.

Abstract: A bonded-wafer semiconductor device includes a semiconductor substrate, a buried oxide layer disposed on a first main surface of the semiconductor substrate and a multi-layer device stack. The multi-layer device stack includes a first device layer of a first conductivity disposed on the buried oxide layer, a second device layer of a second conductivity disposed on the first device layer, a third device layer of the first conductivity disposed on the second device layer and a fourth device layer of the second conductivity disposed on the third device layer. A trench is formed in the multi-layer device stack. A mesa is defined by the trench. The mesa has first and second sidewalls. A first anode/cathode layer is disposed on a first sidewall of the multi-layer device stack, and a second anode/cathode layer is disposed on the second sidewall of the multi-layer device stack.

Abstract: A semiconductor device includes: a semiconductor substrate; an IGBT cell; and a diode cell. The substrate includes a first layer on a first surface, second and third layers adjacently arranged on a second surface of the substrate and a fourth layer between the first layer and the second and third layers. The first layer provides a drift layer of the IGBT cell and the diode cell. The second layer provides a collector layer of the IGBT cell. The third layer provides one electrode connection layer of the diode cell. A resistivity ?1 and a thickness L1 of the first layer, a resistivity ?2 and a thickness L2 of the fourth layer, and a half of a minimum width W2 of the second layer on a substrate plane have a relationship of (?1/?2)×(L1·L2/W22)<1.6.

Abstract: A semiconductor substrate has a trench in a first main surface. An insulated gate field effect part includes a gate electrode formed in the first main surface. A potential fixing electrode fills the trench and has an expanding part expanding on the first main surface so that a width thereof is larger than the width of the trench. An emitter electrode is formed on the first main surface and insulated from the gate electrode electrically and connected to a whole upper surface of the expanding part of the potential fixing electrode. Thus, a semiconductor device capable of enhancing reliability in order to prevent an aluminum spike from generating and a manufacturing method thereof can be provided.

Abstract: A trench-type insulated-gate semiconductor device is disclosed that includes unit cells having a trench gate structure that are scattered uniformly throughout the active region of the device. The impurity concentration in the portion of a p-type base region, sandwiched between an n+-type emitter region and an n-type drift layer and in contact with a gate electrode formed in the trench via a gate insulator film, is the lowest in the portion thereof sandwiched between the bottom plane of n+-type emitter regions and the bottom plane of p-type base region and parallel to the major surface of a silicon substrate. The trench-type insulate-gate semiconductor device according to the invention minimizes the variation of the gate threshold voltage.

Abstract: A semiconductor device and/or a method for fabricating a semiconductor device (e.g. fabricating an LIGBT) that may minimize occurrences of latch-up due to increases of hole current. A semiconductor device and/or a method of fabricating a semiconductor device that may prevent and/or eliminate latch-up due to operation of a parasitic thyrister without significantly deteriorating performances of significant parameters considered when fabricating a high voltage power control device.

Abstract: An image sensor provides enhanced integration of transistor circuitry and photo diodes. The image sensor simultaneously improves resolution and sensitivity. An image sensor an a method for manufacturing prevents defects in a photo diode by adopting a vertical photo diode structure. An image sensor includes a substrate which may include at least one circuit element. A bottom electrode and a first conductive layer may be sequentially formed over the substrate. A strained intrinsic layer may be formed over the first conductive layer. A second conductive layer may be formed over the strained intrinsic layer. An upper electrode may be formed over the second conductive layer.

Abstract: This invention provides methods for fabricating thin film electronic devices with both front- and backside processing capabilities. Using these methods, high temperature processing steps may be carried out during both frontside and backside processing. The methods are well-suited for fabricating back-gate and double-gate field effect transistors, double-sided bipolar transistors and 3D integrated circuits.

Abstract: A semiconductor device fabrication method and a semiconductor layer formation method for making a semiconductor layer having excellent morphology selectively epitaxial-grow over a semiconductor, and a semiconductor device. When a recessed source/drain pMOSFET is fabricated, a gate electrode is formed over a Si substrate in which STIs are formed with a gate insulating film therebetween (step S1). After a side wall is formed (step S2), recesses are formed in portions of the Si substrate on both sides of the side wall (step S3). A SiGe layer including a lower layer portion and an upper layer portion is formed in the recesses of the Si substrate. The lower layer portion and the upper layer portion included in the SiGe layer are made to epitaxial-grow under a condition that growth selectivity of the lower layer portion with respect to the side wall and the STIs is lower than growth selectivity of the upper layer portion with respect to the side wall and the STIs (steps S4 and S5).

Abstract: A method is provided for forming a matching thermal expansion interface between silicon (Si) and gallium nitride (GaN) films. The method provides a (111) Si substrate with a first thermal expansion coefficient (TEC), and forms a silicon-germanium (SiGe) film overlying the Si substrate. A buffer layer is deposited overlying the SiGe film. The buffer layer may be aluminum nitride (AlN) or aluminum-gallium nitride (AlGaN). A GaN film is deposited overlying the buffer layer having a second TEC, greater than the first TEC. The SiGe film has a third TEC, with a value in between the first and second TECs. In one aspect, a graded SiGe film may be formed having a Ge content ratio in a range of about 0% to 50%, where the Ge content increases with the graded SiGe film thickness.

Abstract: A nitride semiconductor device according to the present invention includes: a nitride semiconductor laminated structure comprising a first layer made of a Group III nitride semiconductor, a second layer laminated on the first layer and made of an Al-containing Group III nitride semiconductor with a composition that differs from that of the first layer, the nitride semiconductor laminated structure comprising a stripe-like trench exposing a lamination boundary between the first layer and the second layer; a gate electrode formed to oppose the lamination boundary; and a source electrode and a drain electrode, having the gate electrode interposed therebetween, each connected electrically to the second layer.

Abstract: In a semiconductor device in which a diode and a high electron mobility transistor are incorporated in the same semiconductor chip, a compound semiconductor layer of the high electron mobility transistor is formed on a main surface (first main surface) of a semiconductor substrate of the diode, and an anode electrode of the diode is electrically connected to an anode region via a conductive material embedded in a via hole (hole) reaching a p+ region which is the anode region of the main surface of the semiconductor substrate from a main surface of the compound semiconductor layer.

Abstract: A unit cell for an integrated circuit includes a first conductive type active region and a second conductive type active region which extend in a first direction. Each of the active regions has first and second ends. The first end of the second conductive type active region opposes the second end of the first conductive type active region. A poly-silicon pattern extends in the first direction across the first conductive type active region and second conductive type active region. A first contact region is adjacent the first end of the first conductive type active region in the first direction. A second contact region is adjacent the second end of the second conductive type active region in the first direction.

Abstract: A semiconductor memory device is constructed to include a memory cell formed by a plurality of transistors, wherein each of gate wiring layers of all of the transistors forming the memory cell is arranged to extend in one direction.

Abstract: An open-base semiconductor diode device has an emitter, base, and collector layers. The layers are configured and doped such that the device has an IV characteristic with: i. a punchthrough region beginning at a voltage Vpt with positive resistance, followed by, and ii. an avalanche region including a positive resistance stage beginning with conductivity modulation at Vcrit and Icrit and having a resistance Rcrit, iii. wherein the values of Vcrit, Icrit and Rcrit are set according to the layer configuration and doping. The device may have a double-base structure, and the width of a lower-doped base region may be minimised such that current density Jcrit at which the conductivity modulation occurs due to avalanche is increased. In one example, the device comprises a N-N+ or a P-P+ double-emitter. Thickness of N? or P? layers may be minimised such that the current-carrying capability is maximised and the doping of this layer does not affect the current-carrying capability of the device.

Abstract: A pixel cell array architecture having a dual conversion gain. A dual conversion gain element is coupled between a floating diffusion region and a respective storage capacitor. The dual conversion gain element having a control gate switches in the capacitance of the capacitor to change the conversion gain of the floating diffusion region from a first conversion gain to a second conversion gain. In order to increase the efficient use of space, the dual conversion gain element gate also functions as the bottom plate of the capacitor. In one particular embodiment of the invention, a high dynamic range transistor is used in conjunction with a pixel cell having a capacitor-DCG gate combination; in another embodiment, adjacent pixels share pixel components, including the capacitor-DCG combination.

Abstract: It is an object of the present invention to provide a solid-state imaging device that can achieve a high sensitivity, finer pixels for increasing the number of pixels, a high-speed operation, and high image quality, and a method for manufacturing the same. There are provided a plurality of photoelectric conversion portions arranged in a matrix on a substrate, a vertical transfer channel arranged between vertical columns of the photoelectric conversion portions, a plurality of vertical transfer electrodes for transferring a charge of the photoelectric conversion portions to the vertical transfer channel, a light-shielding film that is laminated on the vertical transfer electrodes via a first insulating film and has a plurality of window portions, each defining a light-receiving portion of each of the photoelectric conversion portions, and a shunt wiring that is arranged in a region overlapping the vertical transfer channel and is insulated from the light-shielding film by a second insulating film.

Abstract: An imager pixel and imaging device and system including an imager pixel for discharging a floating diffusion region are described. The imager pixel includes a photoconversion regions floating diffusion region, and a reset diode. A reset diode is coupled to the floating diffusion region and, when activated, discharges accumulated and collected charge from the photoconversion and the floating diffusion regions. Following successive accumulation, transfer and collection processes, the reset diode again discharges residual accumulated and collected charge from the photoconversion and the floating diffusion regions.

Abstract: Disclosed are embodiments of a field effect transistor (FET) having decreased drive current temperature sensitivity. Specifically, any temperature-dependent carrier mobility change in the FET channel region is simultaneously counteracted by an opposite strain-dependent carrier mobility change to ensure that drive current remains approximately constant or at least within a predetermined range in response to temperature variations. This opposite strain-dependent carrier mobility change is provided by a straining structure that is configured to impart a temperature-dependent amount of a pre-selected strain type on the channel region. Also disclosed are embodiments of an associated method of forming the field effect transistor.

Abstract: A semiconductor radiation detector comprises a bulk layer of semiconductor material, and on a first surface of the bulk layer in the following order: a modified internal gate layer of semiconductor of second conductivity type, a barrier layer of semiconductor of first conductivity type and pixel dopings of semiconductor of the second conductivity type. The pixel dopings are adapted to be coupled to at least one pixel voltage in order to create pixels corresponding to pixel dopings. The device comprises a first conductivity type first contact. Said pixel voltage is defined as a potential difference between the pixel doping and the first contact. The bulk layer is of the first conductivity type. On a second surface of the bulk layer opposite to the first surface, there is nonconductive back side layer that would transport secondary charges outside the active area of the device or function as the radiation entry window.

Abstract: A junction field effect transistor (JFET) has a hyperabrupt junction layer that functions as a channel of a JFET. The hyperabrupt junction layer is formed by two dopant profiles of opposite types such that one dopant concentration profile has a peak concentration depth at a tail end of the other dopant profile. The voltage bias to the channel is provided by a body that is doped with the same type of dopants as the gate. This is in contrast with conventional JFETs that have a body that is doped with the opposite conductivity type as the gate. The body may be electrically decoupled from the substrate by another reverse bias junction formed either between the body and the substrate or between a buried conductor layer beneath the body and the substrate. The capability to form a thin hyperabrupt junction layer allows formation of a JFET in a semiconductor-on-insulator substrate.

Abstract: A trench is formed in the surface of a provided semiconductor body. An oxide is deposited in the trench and a cap is deposited on the oxide, wherein the combination of the cap and the oxide impart a mechanical stress on the semiconductor body.

Abstract: The present invention discloses semiconductor devices that can be manufactured utilizing standard process of manufacturing and that can hold information. In accordance with a presently preferred embodiment of the present invention, one or more semiconductor devices can be formed in a well on a substrate where isolation trenches surround one or more devices to create storage regions (floating wells) that is capable of holding a charge. Depending on the charge in the storage region (floating well), it can represent information. The semiconductor devices of the present invention can be manufactured using the standard process of manufacturing (bulk cmos processing).

Abstract: A photodetector array includes a semiconductor substrate having opposing first and second main surfaces, a first layer of a first doping concentration proximate the first main surface, and a second layer of a second doping concentration proximate the second main surface. The photodetector includes at least one conductive via formed in the first main surface and an anode/cathode region proximate the first main surface and the at least one conductive via. The via extends to the second main surface. The conductive via is isolated from the semiconductor substrate by a first dielectric material. The anode/cathode region is a second conductivity opposite to the first conductivity. The photodetector includes a doped isolation region of a third doping concentration formed in the first main surface and extending through the first layer of the semiconductor substrate to at least the second layer of the semiconductor substrate.

Abstract: Multi-layer antireflection coatings, devices including multi-layer antireflection coatings and methods of forming the same are disclosed. A block copolymer is applied to a substrate and self-assembled into parallel lamellae above a substrate.

Abstract: Disclosed are an image sensor and a method for fabricating the same. The method may include forming a gate, a photo diode, and a floating diffusion region on a pixel region of a semiconductor substrate; forming an oxide film on the pixel region and on an edge region of the semiconductor substrate; forming a sacrificial oxide layer by etching the oxide film using a photoresist pattern as a mask; forming a metal layer on the photoresist pattern, the gate, and the floating diffusion region; forming a salicide layer on the gate and the floating diffusion region; etching a remaining non-salicided portion of the metal layer, the photoresist pattern, and at least a portion of the sacrificial oxide layer; and forming an interlayer insulating film on the semiconductor substrate and planarizing the interlayer insulating film.

Abstract: An image sensor having a plurality of pixels; each pixel includes one or more photosensitive elements that collect charge in response to incident light; one or more transfer mechanisms that respectively transfer the charge from the one or more photosensitive elements; a charge-to-voltage conversion region having a capacitance, and the charge-to-voltage region receives the charge from the one or more photosensitive elements; a first reset transistor connected to the charge-to-voltage conversion region; a second reset transistor connected to the first reset transistor, which in combination with the first reset transistor, selectively sets the capacitance of the charge-to-voltage conversion regions from a plurality of capacitances.

Abstract: An image sensor for minimizing a dark level defect is disclosed. The image sensor includes an isolation layer formed on a substrate. A field region and an active region are defined on the substrate by the isolation layer. A photodiode is formed in the image sensor in such a structure that a first region is formed below a surface of the substrate in the active region and a second region is formed under the first region. A first conductive type impurity is implanted into the first region and a second conductive type impurity is implanted into the second region. A dark current suppressor is formed on side and bottom surfaces of the isolation layer adjacent to the first region, and the dark current suppressor is doped with the second conductive type impurity. The dark current suppressor suppresses the dark current to minimize the dark level defect caused by the dark current.

Abstract: A trench capacitor and method of forming a trench capacitor. The trench capacitor including: a trench in a single-crystal silicon substrate, a conformal dielectric liner on the sidewalls and the bottom of the trench; an electrically conductive polysilicon inner plate filling regions of the trench not filled by the liner; an electrically conductive doped outer plate in the substrate surrounding the sidewalls and the bottom of the trench; a doped silicon region in the substrate; a first electrically conductive metal silicide layer on a surface region of the doped silicon region exposed at the top surface of the substrate; a second electrically conductive metal silicide layer on a surface region of the inner plate exposed at the top surface of the substrate; and an insulating ring on the top surface of the substrate between the first and second metal silicide layers.

Abstract: A capacitor pair structure for increasing the match thereof has two finger electrode structures interlacing with each other in parallel and a common electrode being between the two finger electrode structures to form a capacitor pair structure with an appropriate ratio. Also, the capacitor pair structure could further increase its entire capacitance through vias connecting the same capacitor pair structures on different metal layers.

Abstract: A capacitor pair structure for increasing the match thereof has two finger electrode structures interlacing with each other in parallel and a common electrode being between the two finger electrode structures to form a capacitor pair structure with an appropriate ratio. Also, the capacitor pair structure could further increase its entire capacitance through vias connecting the same capacitor pair structures on different metal layers.

Abstract: A semiconductor device 1 includes MOS transistors 10 and 70 and a MOS varactor 20. The transistors 10 and 70 and the varactor 20 are formed in the same semiconductor substrate 30. The gate insulating films 15 and 75 of the transistors 10 and 70 are the thinnest gate insulating films in the gate insulating films of the transistor formed in the semiconductor substrate 30. The thickness of the gate insulating film 25 of the varactor 20 is larger than the thickness of the gate insulating films 15 and 75.

Abstract: The invention relates to FETs with stripe cells (6). Some of the cells have alternating low and high threshold regions (10, 8) along their length. In a linear operations regime, the low threshold regions conduct preferentially and increase the current density, thereby reducing the risk of thermal runaway. By distributing the low threshold regions (10) along the length of the cells (6), the risk of current crowding is reduced.

Abstract: One aspect of the present subject matter relates to a method for forming a transistor. According to an embodiment of the method, a pillar of amorphous semiconductor material is formed on a crystalline substrate, and a solid phase epitaxy process is performed to crystallize the amorphous semiconductor material using the crystalline substrate to seed the crystalline growth. The pillar has a sublithographic thickness. A transistor body is formed in the crystallized semiconductor pillar between a first source/drain region and a second source/drain region. A surrounding gate insulator is formed around the semiconductor pillar, and a surrounding gate is formed around and separated from the semiconductor pillar by the surrounding gate insulator. Other aspects are provided herein.

Abstract: A semiconductor memory device includes a silicon substrate including a first region which has a buried insulating layer below a single-crystal silicon layer and a second region which does not have the buried insulating layer below the single-crystal silicon layer, at least one memory cell transistor which has a first gate electrode, the first gate electrode being provided on the single-crystal silicon layer in the first region, and at least one selective gate transistor which has a second gate electrode and is provided on the single-crystal silicon layer in the first region. The one selective gate transistor is provided in such a manner that a part of the second gate electrode is placed on the single-crystal silicon layer in the second region.

Abstract: Disclosed are a flash memory device and a method of manufacturing the same. In the method of manufacturing the flash memory device, gate patterns of a cell area and a logic area are formed by sequentially depositing and patterning a first polysilicon layer, an ONO layer and a second polysilicon layer without separately performing a photolithography process for one of the gate patterns. A mask process for removing a dummy gate pattern in the logic area is performed to form transistors in the cell area and the logic area, so that the manufacturing process is simplified.

Abstract: Semiconductor devices including a gate electrode crossing over a semiconductor fin on a semiconductor substrate are provided. A gate insulating layer is provided between the gate electrode and the semiconductor fin. A channel region having a three-dimensional structure defined at the semiconductor fin under the gate electrode is also provided. Doped region is provided in the semiconductor fin at either side of the gate electrode and an interlayer insulating layer is provided on a surface of the semiconductor substrate. A connector region is coupled to the doped region and provided in an opening, which penetrates the interlayer insulating layer. A recess region is provided in the doped region and is coupled to the connector region. The connector region contacts an inner surface of the recess region. Related methods of fabricating semiconductor devices are also provided herein.

Abstract: A semiconductor device includes a semiconductor substrate having a plurality of element regions and a plurality of element isolation regions in a first direction, a plurality of floating gate electrodes formed via a gate insulating film on the respective element regions, an intergate insulating film formed on the floating gate electrodes, a plurality of control gate electrodes formed on the intergate insulating film so as to extend over the adjacent floating gate electrodes, and an element isolation insulating film formed in the element isolation region and having an upper end located higher than the upper surface of the gate insulating film, the element isolation insulating film including a part formed between the control gate electrodes so that the central sidewall of the element isolation insulating film is located lower than the end of the sidewall of the element isolation insulating film.

Abstract: A flash memory cell includes a substrate, a T-shaped control gate disposed above the substrate, a floating gate embedded in a lower recess of the T-shaped control gate, a dielectric layer between the T-shaped control gate and the floating gate; a cap layer above the T-shaped control gate, a control gate oxide between the T-shaped control gate and the substrate, a floating gate oxide between the floating gate and the substrate, a liner covering the cap layer and the floating gate, and a source/drain region adjacent to the floating gate. The floating gate has a vertical wall surface that is coplanar with one side of the dielectric layer.