Abstract: This invention intends to develop a technique for forming an interlayer with excellent optical characteristics and to provide a photoelectric conversion device having high conversion efficiency. To realize this purpose, a series connection through an intermediate layer is formed in the thin-film photoelectric conversion device of the invention, and the interlayer is a transparent oxide layer in its front surface and n pairs of layers stacked therebehind (n is an integer of 1 or more), wherein each of the pair of layers is a carbon layer and a transparent oxide layer stacked in this order. Film thicknesses of each layer are optimized to improve wavelength selectivity and stress resistance while keeping the series resistance.

Abstract: A device is provided which includes a transparent substrate. An opaque layer is disposed on the transparent substrate. A conductive layer disposed on the opaque layer. The opaque layer and the conductive layer form a handling layer, which may be used to detect and/or align the transparent wafer during fabrication processes. In an embodiment, the conductive layer includes a highly-doped silicon layer. In an embodiment, the opaque layer includes a metal. In embodiment, the device may include a MEMs device.

Abstract: Provided are a FET-based sensor for detecting an ionic material, an ionic material detecting device including the FET-based sensor, and a method of detecting an ionic material using the FET-based sensor. The FET-based sensor includes: a sensing chamber including a reference electrode and a plurality of sensing FETs; and a reference chamber including a reference electrode and a plurality of reference FETs. The method includes: flowing a first solution into and out of the sensing chamber and the reference chamber of the FET-based sensor; flowing a second solution expected to contain an ionic material into and out of the sensing chamber while continuously flowing the first solution into and out of the reference chamber; measuring a current in a channel region between the source and drain of each of the sensing and reference FETs; and correcting the current of the sensing FETs.

Abstract: A semiconductor device includes a plurality of first cells having a first cell height, and a plurality of second cells having a second cell height. Each of the first cells has a first MIS transistor of a first conductivity type, and a substrate contact region of a second conductivity type. Each of the second cells has a second MIS transistor of the first conductivity type, a power supply region of the first conductivity type, and a first extended region of the first conductivity type that is silicidated at a surface thereof. The first cell height is greater than the second cell height.

Abstract: A bulk GaN layer is on a first surface of a substrate, wherein the bulk GaN layer has a GaN transistor region and a bulk acoustic wave (BAW) device region. A source/drain layer is over a first surface of the bulk GaN layer in the GaN transistor region. A gate electrode is formed over the source/drain layer. A first BAW electrode is formed over the first surface of the bulk GaN layer in the BAW device region. An opening is formed in a second surface of the substrate, opposite the first surface of the substrate, which extends through the substrate and exposes a second surface of the bulk GaN layer, opposite the first surface of the bulk GaN layer. A second BAW electrode is formed within the opening over the second surface of the bulk GaN layer.

Abstract: A microelectromechanical system (MEMS) resonator or filter including a first conductive layer, one or more electrodes patterned in the first conductive layer which serve the function of signal input, signal output, or DC biasing, or some combination of these functions, an evacuated cavity, a resonating member comprised of a lower conductive layer and an upper structural layer, a first air gap between the resonating member and one or more of the electrodes, an upper membrane covering the cavity, and a second air gap between the resonating member and the upper membrane.

Abstract: A hybrid orientation accumulation mode GAA (Gate-All-Around) CMOSFET includes a PMOS region having a first channel, an NMOS region having a second channel and a gate region. The first channel and the second channel have a racetrack-shaped cross section and are formed of p-type Si(110) and n-type Si(100), respectively; the surfaces of the first channel and the second channel are substantially surrounded by the gate region; a buried oxide layer is disposed between the PMOS region and the NMOS region and between the PMOS or NMOS region and the Si substrate to isolate them from one another. The device structure according to the prevent invention is quite simple, compact and highly integrated. In an accumulation mode, current flows through the overall racetrack-shaped channel. The disclosed device results in high carrier mobility. Meanwhile polysilicon gate depletion and short channel effects are prevented, and threshold voltage is increased.

Abstract: Provided is a semiconductor wafer. In the semiconductor wafer, formation and etching of an n type epitaxial layer and formation and etching of a p type epitaxial layer are alternately performed for at least three times, so that all semiconductor layers are formed of epitaxial layers on a semiconductor substrate. Thereby, the respective semiconductor layers can be formed to have reduced widths. Thus, if a required breakdown voltage is the same, dopant concentrations of the respective semiconductor layers can be increased and a resistance value of the wafer can be reduced. In addition, a space portion remaining in the end is buried with an insulating layer, so that a defect can be avoided in a junction surface of the epitaxial layers.

Abstract: According to one exemplary embodiment, an overmolded package includes a component situated on a substrate. The overmolded package further includes an overmold situated over the component and the substrate. The overmolded package further includes a wirebond cage situated over the substrate and in the overmold, where the wirebond cage surrounds the component, and where the wirebond cage includes a number of wirebonds. The wirebond cage forms an EMI shield around the component. According to this exemplary embodiment, the overmolded package further includes a conductive layer situated on a top surface of the overmold and connected to the wirebond cage, where the conductive layer forms an EMI shield over the component.

Abstract: A method for forming a tileable detector array is presented.

Abstract: A disclosed laminated structure includes a substrate; a wettability varying layer formed on the substrate, the wettability varying layer including a material whose critical surface tension is changed by receiving energy; and an electrode layer formed on the wettability varying layer, the electrode layer forming a pattern based on the wettability varying layer. The material whose critical surface tension is changed by receiving energy includes a polymer including a primary chain and a side chain, the side chain including a multi-branched structure.

Abstract: A semiconductor device includes a first semiconductor chip including a first surface, a second surface and a first terminal arranged on the first surface, a second semiconductor chip including a first surface, a second surface and a second terminal arranged on the first surface of the second semiconductor chip, a support substrate including a first surface bonded to the second surfaces of the first semiconductor chip and the second semiconductor chip, and an isolation groove formed on the first surface of the support substrate. The isolation includes a pair of side surfaces continuously extending from opposing side surfaces of the first semiconductor chip and the second semiconductor chip, respectively, and the isolation groove is formed into the support substrate to extend from the first surface of the support substrate. The isolation groove has a depth less than a thickness of the support substrate.

Abstract: A capacitor includes a lower electrode; a dielectric layer formed on a predetermined portion of the lower electrode; an upper electrode formed on the dielectric layer; a hard mask pattern formed on the upper electrode; and an isolation layer having a shape of a spacer, formed on one sidewall of the hard mask pattern, the upper electrode, and the dielectric layer.

Abstract: A chip pad structure of an integrated circuit (IC) and the method of forming are disclosed. The chip pad comprises a main pad portion and a ring pad portion. During a charging process involved in forming the chip pad structure, electrical connections from the gate electrodes of MOS transistors in the IC substrate generally are made only to the ring pad portion that has an antenna-to-gate area ratio substantially below a predetermined antenna design rule ratio, and thus is resistant or immune to antenna effect. The main pad portion and the ring pad portion are coupled together through metal bridges formed in an upper interconnect metal layer or in the top conductive pad layer. The chip pad may be used as probe pads on a parametric testline or bonding pads on an IC.

Abstract: An interconnection system is provided for a solid-state device. The solid-state that includes, a first layer, multiple devices and a first face. A second layer is bonded to the first face at a bonded face of the second layer that faces the first face. Electrically conductive bonds are between the first and second faces. Conductive paths are on the bonded face of the second layer and connect two or more of the conductive bonds.

Abstract: An apparatus including a first die including a plurality of conductive through substrate vias (TSVs); and a plurality of second dice each including a plurality of contact points coupled to the TSVs of the first die, the plurality of second dice arranged to collectively include a surface area approximating a surface area of the first die. A method including arranging a plurality of second dice on a first die such that collectively the plurality of second dice include a surface area approximating the surface area of the first die; and electrically coupling a plurality of second device to a plurality of the first die. A system including an electronic appliance including a printed circuit board and a module, the module including a first die including a plurality of TSVs; and the plurality of second dice arranged to collectively include a surface area approximating the surface area of the first die.

Abstract: Electronic apparatus and methods of forming the electronic apparatus include a lanthanide yttrium aluminum oxide dielectric film on a substrate for use in a variety of electronic systems. The lanthanide yttrium aluminum oxide film may be structured as one or more monolayers. The lanthanide yttrium aluminum oxide film may be formed by atomic layer deposition.

Abstract: An integrated circuit includes a functional block having a plurality of standard cells. The plurality of standard cells includes a plurality of functional standard cells and a filler standard cell. Each functional standard cell of the plurality of functional standard cells has a rectangular boundary. The filler standard cell has a rectangular boundary adjacent to at least one of the functional standard cells. The filler standard cell is selectable between a first state and a second state. The filler standard cell is non-functional in the first state. The filler standard cell has functional test structures coupled to a first metal layer in the second state. This allows for test structures helpful in analyzing functionality of circuit features such as transistors without requiring additional space on the integrated circuit.

Abstract: An image sensor includes a photoelectric converter, a reflector, and a charge carrier guiding region. The reflector is disposed under the photoelectric converter, and the charge carrier guiding region is disposed between the photoelectric converter and the reflector. The reflector reflects incident light passed by the photoelectric converter back through the photoelectric converter for increasing photoelectric conversion efficiency and reduced crosstalk. The charge carrier guiding region dissipates undesired charge carriers for further increasing photoelectric conversion efficiency.

Abstract: Plural I/O cells (14) having electrode pads for wire bonding (13) are disposed with spaces (55) between them in the vicinity of a corner of an I/O region (11) of a semiconductor substrate (10), and power supply separation cells (16) not to be wire bonded, on which ESD (electrostatic discharge) protection circuits (4) having ESD protection transistors are amounted, are disposed between the respective I/O cells (14), whereby the chip size is reduced upon consideration of layout of the electrode pads.

Abstract: A phase change random access memory for actively removing residual heat and a method of manufacturing the same are presented. The phase change random access memory includes a semiconductor substrate, a phase change pattern, a heating electrode and a cooling electrode. The phase change pattern is on the semiconductor substrate. The heating electrode is electrically coupled to the phase change pattern for heating the phase change pattern. The cooling electrode is electrically coupled to the phase change pattern for removing residual heat from the phase change pattern.

Abstract: The present invention relates to a thin film transistor, a method thereof and an organic light emitting device including the thin film transistor. According to an embodiment of the present invention, the thin film transistor includes a substrate, a control electrode, an insulating layer, a first electrode and a second electrode, a first ohmic contact layer and a second ohmic contact layer, and a semiconductor layer. The control electrode is formed on the substrate, and the insulating layer is formed on the control electrode. The first and the second electrodes are formed on the insulating layer. The first ohmic contact layer and the second ohmic contact layer are formed on the first electrode and the second electrode. The semiconductor layer is formed on the first ohmic contact layer and the second ohmic contact layer to fill between the first and the second electrodes.

Abstract: Provided is a semiconductor element including: a semiconductor having an active layer; a gate insulating film which is in contact with the semiconductor; a gate electrode opposite to the active layer through the gate insulating film; a first nitride insulating film formed over the active layer; a photosensitive organic resin film formed on the first nitride insulating film; a second nitride insulating film formed on the photosensitive organic resin film; and a wiring provided on the second nitride insulating film, in which a first opening portion is provided in the photosensitive organic resin film, an inner wall surface of the first opening portion is covered with the second nitride insulating film, a second opening portion is provided in a laminate including the gate insulating film, the first nitride insulating film, and the second nitride insulating film inside the first opening portion, and the semiconductor is connected with the wiring through the first opening portion and the second opening portion.

Abstract: A modified layer 5 and an altered layer 8 are formed outside a dicing point of a dicing area 3. Thus without forming another interface between different physical properties on the dicing point, it is possible to prevent chipping from progressing along a crystal orientation from an interface between a semiconductor element 2 and a semiconductor substrate 1 and from a surface of the semiconductor element during dicing, thereby suppressing the development of chipping to the semiconductor element.

Abstract: In a semiconductor element (20) including a field effect transistor (90), a schottky electrode (9a) and a plurality of bonding pads (12S, 12G), at least one of the plurality of bonding pads (12S, 12G) is disposed so as to be located above the schottky electrode (9a).

Abstract: The present invention provides a high speed and low power consumption LSI operable in a wide temperature range in which a MOS transistor having back gates is used specifically according to operating characteristics of a circuit. In the LSI, an FD-SOI structure having an embedded oxide film layer is used and a lower semiconductor region of the embedded oxide film layer is used as a back gate. A voltage for back gates in the logic circuits having a small load in the logic circuit block is controlled in response to activation of the block from outside of the block. Transistors, in which the gate and the back gate are connected to each other, are used for the circuit generating the back gate driving signal, and logic circuits having a heavy load such as circuit block output section, and the back gates are directly controlled according to the gate input signal.

Abstract: A method for manufacturing carbon nanotubes includes the steps of: (a) depositing catalytic fine particles containing Al—Fe, Zr—Co or Hf—Co on a base body; and (b) growing carbon nanotubes on the catalytic fine particles deposited on the base body.

Abstract: A semiconductor integrated circuit device includes a semiconductor substrate; a dummy pattern extending in one direction on the semiconductor substrate; a junction region electrically connecting the dummy pattern to the semiconductor substrate; and a voltage applying unit that is configured to apply a bias voltage to the dummy pattern.

Abstract: A thin film transistor (“TFT”) substrate in which the size of a pixel TFT formed in a display area is reduced using a single slit mask, and the length of the channel area of a protection TFT constituting an electrostatic discharge protection circuit formed in a non-display area is formed larger than that of the pixel TFT using the same mask pattern. The TFT substrate includes a signal line and a discharge line formed on a substrate, a signal supply pad formed on one end of the signal line to supply a signal to the signal line, and an electrostatic discharge protection circuit including at least one protection TFT including a plurality of channels formed between the signal supply pad and the discharge line and/or between the signal line and the discharge line.

Abstract: Disclosed is display part such as a TFT array panel comprising an aluminum layer, and a molybdenum layer formed on the aluminum layer. The thickness of the molybdenum layer may be about 10% to about 40% the thickness of the aluminum layer. As a result, a top surface of the aluminum layer may have a width about equal to a bottom surface of the molybdenum layer. Accordingly, it is an aspect of the present invention to provide a TFT array panel comprising an aluminum wiring on which aluminum protrusion is reduced or eliminated.

Abstract: The present invention provides an active matrix type display device having a high aperture ratio and a required auxiliary capacitor. A source line and a gate line are overlapped with part of a pixel electrode. This overlapped region functions to be a black matrix. Further, an electrode pattern made of the same material as the pixel electrode is disposed to form the auxiliary capacitor by utilizing the pixel electrode. It allows a required value of auxiliary capacitor to be obtained without dropping the aperture ratio. Also, it allows the electrode pattern to function as a electrically shielding film for suppressing the cross-talk between the source and gate lines and the pixel electrode.

Abstract: A thermopile infrared sensor array, comprises a sensor chip with a number of thermopile sensor elements, made from a semiconductor substrate and corresponding electronic components. The sensor chip is mounted on a support circuit board and enclosed by a cap in which a lens is arranged. The aim is the production of a monolithic infrared sensor array with a high thermal resolution capacity with a small chip size and which may be economically produced. The aim is achieved by arranging a thin membrane made from non-conducting material on the semiconductor substrate of the sensor chip on which the thermopile sensor elements are located in an array. Under each thermopile sensor element, the back side of the membrane is uncovered in a honeycomb pattern by etching and the electronic components are arranged in the boundary region of the sensor chip. An individual pre-amplifier with a subsequent low-pass filter may be provided for each column and each row of sensor elements.

Abstract: A sensor is disclosed. A representative sensor includes a silicon substrate having a porous silicon region. A portion of the porous silicon region has a front contact is disposed thereon. The contact resistance between the porous silicon region and the front contact is between about 10 ohms and 100 ohms.

Abstract: A semiconductor nanocrystal heterostructure has a core of a first semiconductor material surrounded by an overcoating of a second semiconductor material. Upon excitation, one carrier can be substantially confined to the core and the other carrier can be substantially confined to the overcoating.

Abstract: A catalytic element is added to an amorphous semiconductor film and heat treatment is conducted therefor to produce a crystalline semiconductor film with good quality, a TFT (semiconductor device) with a satisfactory characteristic is realized using the crystalline semiconductor film. A semiconductor layer includes a region containing an impurity element which has a concentration of 1×1019/cm3 to 1×1021/cm3 and belongs to group 15 of the periodic table and an impurity element which has a concentration of 1.5×1019/cm3 to 3×1021/cm3 and belongs to group 13 of the periodic table, and the region is a region to which a catalytic element left in the semiconductor film (particularly, the channel forming region) moves.

Abstract: An integrated circuit includes a functional block having a plurality of standard cells. The plurality of standard cells includes a plurality of functional standard cells and a filler standard cell. Each functional standard cell of the plurality of functional standard cells has a rectangular boundary. The filler standard cell has a rectangular boundary adjacent to at least one of the functional standard cells. The filler standard cell is selectable between a first state and a second state. The filler standard cell is non-functional in the first state. The filler standard cell has functional test structures coupled to a first metal layer in the second state. This allows for test structures helpful in analyzing functionality of circuit features such as transistors without requiring additional space on the integrated circuit.

Abstract: The present invention provides a high speed and low power consumption LSI operable in a wide temperature range in which a MOS transistor having back gates is used specifically according to operating characteristics of a circuit. In the LSI, an FD-SOI structure having an embedded oxide film layer is used and a lower semiconductor region of the embedded oxide film layer is used as a back gate. A voltage for back gates in the logic circuits having a small load in the logic circuit block is controlled in response to activation of the block from outside of the block. Transistors, in which the gate and the back gate are connected to each other, are used for the circuit generating the back gate driving signal, and logic circuits having a heavy load such as circuit block output section, and the back gates are directly controlled according to the gate input signal.

Abstract: A thin film transistor array panel includes a substrate; a first gate line disposed on the substrate and including a gate electrode; a storage electrode disposed in a layer which is the same layer as a layer of the first gate line; a gate insulating layer disposed on the first gate line and the storage electrode; a semiconductor disposed on the gate insulating layer and including a channel portion; a data line disposed on the semiconductor and including a source electrode; a drain electrode disposed on the semiconductor and facing the source electrode; a passivation layer disposed on the gate insulating layer, the data line, and the drain electrode, the passivation layer including a contact hole which exposes a portion of the drain electrode; and a pixel electrode disposed on the passivation layer and electrically connected to the drain electrode through the contact hole, wherein the gate insulating layer and the passivation layer are interposed between the pixel electrode and the substrate except for a regio

Abstract: The present invention relates to a semiconductor device and a method of manufacture thereof, being capable of improving the high integration by increasing a cell region while securing the reliability of device and the process margin through forming a cell region and a core region with the stacking structure.

Abstract: A method for manufacturing a semiconductor device, including the steps of: forming a shielding film 38 on a first insulating film 37; sequentially forming a second insulating film 39 and an amorphous semiconductor film 40 on the shielding film 38; melting the amorphous semiconductor film 40 at least in portions to be channels of thin-film transistors by irradiating an energy beam onto the amorphous semiconductor film 40, and converting the amorphous semiconductor film 40 into a polycrystalline semiconductor film 41; sequentially forming a gate insulating film 43a and a gate electrode 44a on the polycrystalline semiconductor film 41 on the channels; and forming source and drain regions 41a in the polycrystalline semiconductor film 41 on sides of the gate electrode 44a, and forming a TFT 60 by use of the source and drain regions 41a, the gate insulating film 43a, and the gate electrode 44a.

Abstract: Provided are an electrical fuse, a semiconductor device having the same, and a method of programming and reading the electrical fuse. The electrical fuse includes first and second anodes disposed apart from each other. A cathode is interposed between the first and second anodes. A first fuse link couples the first anode to the cathode, and a second fuse link couples the second anode to the cathode.

Abstract: A light emitting device package and a lighting system are provided. According to one embodiment, a functional substrate; at least one light emitting element bonded onto the functional substrate; and at least one design-in thermal detection unit built onto the functional substrate are provided, wherein the design-in thermal detection unit is proximate to the light emitting element, and wherein the design-in thermal detection unit is configured to detect the temperature and transmit a temperature signal. The design-in thermal detection unit may be an NTC thermistor based on a semiconductor substrate. A control system may be included to detect temperature and make any necessary current adjustments in order to maintain consistent performance of the light emitting element.

Abstract: A system for displaying images. The system comprises a thin film transistor (TFT) device comprising a substrate having a pixel region. An active layer is disposed on the substrate of the pixel region, comprising a channel region, a pair of source/drain regions separated by the channel region. The channel region comprises dopants with a first conductivity type and a second conductivity type opposite to the first conductivity type. A gate structure is disposed on the active layer, comprising a stack of a gate dielectric layer and a gate layer. A method for fabricating a system for displaying images including the TFT device is also disclosed.

Abstract: A dual panel type organic electroluminescent display device includes first and second substrates and a plurality of pixel regions and a plurality of power supply terminals at upper and lower sides of the plurality of pixel regions thereon, and further includes a plurality of dummy pixel regions each having substantially the same structure as each pixel region in the plurality of power supply terminals.

Abstract: According to one exemplary embodiment, a semiconductor die including at least one deep trench isolation region for isolating an electronic device (for example, a bipolar device) includes a trench situated in a substrate of the semiconductor die, where the trench has sides surrounding the electronic device, and where the trench has at least one trench chamfered corner formed between and connecting the sides of the trench. The at least one trench chamferred corner is formed between a chamfered corner of an outside wall of said trench and a corner of an inside wall of the trench. A trench corner width at the at least one trench chamfered corner is less than a trench side width along the sides of the trench.

Abstract: A thin film transistor (TFT), a method of fabricating the same, and a display device including the TFT, are provided. The method includes forming an edge region that is doped with impurities of a conductivity type opposite to a conductivity type of impurities doped into source and drain regions. The edge region is in contact with a channel region and an edge portion of the source region. The method also includes forming contact holes for source and drain electrodes to expose a portion of the drain region and expose respective portions of the source region and the edge region contacting the edge portion of the source region; and forming source and drain electrodes. Thus, a source-body contact is automatically formed so that an edge effect can be reduced and a kink effect can be reduced or removed.

Abstract: The present invention provides a thin film transistor array panel which includes a substrate, gate lines formed on the substrate, polycrystalline semiconductors formed on the gate lines, data lines formed on the polycrystalline semiconductors and including first electrodes, second electrodes formed on the polycrystalline semiconductors and facing the first electrodes, and pixel electrodes connected to the second electrodes.

Abstract: Systems and methods for local synthesis of silicon nanowires and carbon nanotubes, as well as electric field assisted self-assembly of silicon nanowires and carbon nanotubes, are described. By employing localized heating in the growth of the nanowires or nanotubes, the structures can be synthesized on a device in a room temperature chamber without the device being subjected to overall heating. The method is localized and selective, and provides for a suspended microstructure to achieve the thermal requirement for vapor deposition synthesis, while the remainder of the chip or substrate remains at room temperature. Furthermore, by employing electric field assisted self-assembly techniques according to the present invention, it is not necessary to grow the nanotubes and nanowires and separately connect them to a device. Instead, the present invention provides for self-assembly of the nanotubes and nanowires on the devices themselves, thus providing for nano- to micro-integration.

Abstract: Logic LSI includes first power domains PD1 to PD4, thick-film power switches SW1 to SW4, and power switch controllers PSWC1 to PSWC4. The thick-film power switches are formed by thick-film power transistors manufactured in a process common to external input/output circuits I/O. The first power domains include second power domains SPD11 to SPD42 including logic blocks, control circuit blocks SCB1 to SCB4, and thin-film power switches SWN11 to SWN42 that are connected to the thick-film power switches via virtual ground lines VSSM1 to VSSM4, and formed by thin-film power transistors manufactured in a process common to the logic blocks. In this way, power switches having different thickness of gate insulating films from one another are vertically stacked so as to be in a hierarchical structure, and each power switch is individually controlled by a power switch controller and a control circuit block correspondingly to each mode.

Abstract: A method of forming a semiconductor sensor in one embodiment includes providing a substrate, forming a reflective layer on the substrate, forming a sacrificial layer on the reflective layer, forming an absorber layer with a thickness of less than about 50 nm on the sacrificial layer, forming an absorber in the absorber layer integrally with at least one suspension leg, and removing the sacrificial layer.