Abstract: A semiconductor light-emitting device comprises an N-type semiconductor layer, an active layer formed on the surface of the N-type semiconductor layer, a P-type semiconductor layer formed on the surface of the active layer, and a reflective layer formed on the surface of the P-type semiconductor layer. A plurality of ohmic contact blocks with electrical properties of ohmic contact are on the surface of the reflective layer adjacent to the P-type semiconductor layer, and the remaining part of the surface acts as the reflective regions with higher reflectivity, and the reflective regions can effectively reflect the light generated from the active layer.

Abstract: A semiconductor light-emitting device, the device includes a substrate, a semiconductor stacked layer, a lead electrode and a lead, wherein the semiconductor stacked layer at least includes a N-type layer and a P-type layer, at least one of the N-type layer and the P-type layer has an opening, the opening is just beneath the lead; or includes a conductive substrate having a main surface and a back surface, an adhesive metal layer, a reflective/ohmic metal layer, a semiconductor stacked layer, a lead electrode and a lead sequentially deposited on the main surface of the substrate, the reflective/ohmic metal layer has an opening, the opening is just beneath the lead.

Abstract: A semiconductor device includes a p-type nitride semiconductor layer (14); and a p-side electrode (18) including a palladium oxide film (30) connected to a surface of the nitride semiconductor layer (14).

Abstract: An organic light-emitting device including a transparent conducting oxide layer as a cathode and a method of manufacturing the organic light-emitting device. The organic light-emitting device includes an anode disposed on a substrate. An organic functional layer including at least an organic light-emitting layer is disposed on the anode. The transparent conducting oxide layer used as the cathode is disposed on the organic functional layer. The transparent conducting oxide layer cathode is formed by plasma-assisted thermal evaporation. A microcavity structure is not formed in the organic light-emitting device, thereby avoiding a luminance change and a color shift as a function of viewing angle.

Abstract: A light emitting apparatus includes: a light emitting element including a laminated body, an electrode provided on the laminated body, and a pad electrode provided on the electrode, the laminated body including a semiconductor light emitting layer; a mounting member having a metal bonding layer; and an alloy solder containing gold for bonding the pad electrode to the metal bonding layer. The pad electrode has at least a first gold layer provided on the electrode and being thicker than the electrode and a first metal barrier layer provided on the first gold layer, and the melting point of the alloy solder is lower than the melting point of alloys with elements constituting the first metal barrier layer and the alloy solder.

Abstract: The present invention relates to an electronic component assembly including a composite material carrier, a circuit carrier made of a dielectric material, a circuit with a conductive material formed on the circuit carrier, an intermediate layer between the circuit carrier and the composite material carrier, and an electronic component arranged on the composite material carrier and electrically connecting to the circuit.

Abstract: An object of the present invention is to provide a method for producing a p-type Group III nitride semiconductor which can be used to produce a light-emitting device exhibiting a low operation voltage and a sufficiently high reverse voltage. The inventive method for producing a p-type Group III nitride semiconductor comprises, during lowering temperature after completion of growth of a Group III nitride semiconductor containing a p-type dopant, immediately after completion of the growth, starting, at a temperature at which the growth has been completed, supply of a carrier gas composed of an inert gas and reduction of the flow rate of a nitrogen source; and stopping supply of the nitrogen source at a time in the course of lowering the temperature.

Abstract: A self-supported nitride semiconductor substrate of 10 mm or more in diameter having an X-ray diffraction half width of 500 seconds or less in at least one of a {20-24} diffraction plane and a {11-24} diffraction plane.

Abstract: A semiconductor component comprising a monocrystalline semiconductor body, and to a method for producing the same is disclosed. In one embodiment, the semiconductor body has a semiconductor component structure with regions of a porous-mono crystalline semiconductor.

Abstract: Methods of forming a suicide in an embedded silicon germanium (eSiGe) source/drain region using a suicide prevention spacer overlapping an interface between the eSiGe and the silicon channel, and a related PFET with an eSiGe source/drain region and a compressive stress liner in close proximity to a silicon channel thereof, are disclosed. In one embodiment, a method includes providing a gate having a nitrogen-containing spacer adjacent thereto and an epitaxially grown silicon germanium (eSiGe) region adjacent to a silicon channel of the gate; removing the nitrogen-containing spacer that does not extend over the interface between the eSiGe source/drain region and the silicon channel; forming a single silicide prevention spacer about the gate, the single silicide prevention spacer overlapping the interface; and forming the silicide in the eSiGe source/drain region using the single silicide prevention spacer to prevent the silicide from forming in at least an extension area of the silicon channel.

Abstract: A composite semiconductor structure and method of forming the same are provided. The composite semiconductor structure includes a first silicon-containing compound layer comprising an element selected from the group consisting essentially of germanium and carbon; a silicon layer on the first silicon-containing compound layer, wherein the silicon layer comprises substantially pure silicon; and a second silicon-containing compound layer comprising the element on the silicon layer. The first and the second silicon-containing compound layers have substantially lower silicon concentrations than the silicon layer. The composite semiconductor structure may be formed as source/drain regions of metal-oxide-semiconductor (MOS) devices.

Abstract: Gallium nitride material transistors and methods associated with the same are provided. The transistors may be used in power applications by amplifying an input signal to produce an output signal having increased power. The transistors may be designed to transmit the majority of the output signal within a specific transmission channel (defined in terms of frequency), while minimizing transmission in adjacent channels. This ability gives the transistors excellent linearity which results in high signal quality and limits errors in transmitted data. The transistors may be designed to achieve low ACPR values (a measure of excellent linearity), while still operating at high drain efficiencies and/or high output powers. Such properties enable the transistors to be used in RF power applications including third generation (3G) power applications based on W-CDMA modulation.

Abstract: A method of fabrication and a field effect device structure are presented that reduce source/drain capacitance and allow for device body contact. A Si based material pedestal is produced, the top surface and the sidewalls of which are oriented in a way to be substantially parallel with selected crystallographic planes of the pedestal and of a supporting member. The pedestal is wet etched with an anisotropic solution containing ammonium hydroxide. The sidewalls of the pedestal become faceted forming a segment in the pedestal with a reduced cross section. The dopant concentration in the reduced cross section segment is chosen to be sufficiently high for it to provide for electrical continuity through the pedestal.

Abstract: A transistor includes a nitride semiconductor layer and a gate electrode layer. The gate electrode layer includes a tantalum nitride layer being formed on the nitride semiconductor layer. The tantalum nitride layer forms a Schottky junction with the nitride semiconductor layer. The transistor also includes an insulating film formed on the nitride semiconductor layer. The insulating film surrounds the gate electrode layer. The portion of the gate electrode layer in contact with the nitride semiconductor layer has a higher nitrogen mole fraction than the other portion of the gate electrode layer.

Abstract: A stress layer structure disposed on a substrate including a device region and a non-device region is provided. The device region includes active regions and a non-active region. The stress layer structure has stress patterns, at least one partition line, and at least one dummy stress pattern. Each of the stress patterns is disposed on the substrate of each of the active regions, respectively. The partition line exposes a portion of the substrate and divides the two adjacent stress patterns. The dummy stress pattern is disposed on the substrate in the partition line.

Abstract: The field of invention is in the area of MOS integrated circuits operating with very low currents in the weak inversion region or sub threshold. The method aims at providing linear resistor with a value in the multi-mega ohm range. In order to produce Silicon based high resistance value, the claimed invention provides a semiconductor resistance using MOS transistor comprising a gate, drain, source and body terminals wherein the body terminal is tied to the drain terminal, the voltage applied between the source and the gate defining the resistance value.

Abstract: The present disclosure provides an image sensor semiconductor device. The semiconductor device includes a semiconductor substrate; a first epitaxy semiconductor layer disposed on the semiconductor substrate and having a first type of dopant and a first doping concentration; a second epitaxy semiconductor layer disposed over the first epitaxy semiconductor layer and having the first type of dopant and a second doping concentration less than the first doping concentration; and an image sensor on the second epitaxy semiconductor layer.

Abstract: To provide a semiconductor device which can detect low illuminance. A photoelectric conversion element, a diode-connected first transistor, and a second transistor are included. A gate of the first transistor is electrically connected to a gate of the second transistor. One of a source and a drain of the first transistor is electrically connected to one of a source and a drain of the second transistor through the photoelectric conversion element. The other of the source and the drain of the first transistor is electrically connected to the other of the source and the drain of the second transistor. By using transistors which have different threshold voltages for the first transistor and the second transistor, a semiconductor device which can perform detecting of low illuminance can be obtained.

Abstract: An idling time period after applying a bias to a conversion element until a start of an accumulation of the conversion element for deriving an image and an accumulation period from the start of the accumulation to a termination of the accumulation are measured. An offset correction of the image is conducted by using a dark current accumulation charge quantity in the accumulation calculated based on the measured idling time period and accumulation period and stored dark current response characteristics. Thus, even just after applying the bias to the conversion element, the offset correction can be properly conducted. An imaging apparatus which can execute a good radiographing without increasing costs and a size even just after applying the bias to the conversion element is provided.

Abstract: An optic wafer for assembly with an imager wafer, the optic wafer comprising a plurality of reliefs in a surface thereof coincident with street locations separating mutually adjacent optic element locations. A wafer assembly that includes the optic wafer and an imager wafer and methods of dicing a wafer assembly are also disclosed.

Abstract: In a DRAM device and a method of manufacturing the same, a multiple tunnel junction (MTJ) structure is provided, which includes conductive patterns and nonconductive patterns alternately stacked on each other. The nonconductive patterns have a band gap larger than a band gap of the conductive patterns. A gate insulation layer and a gate electrode are formed on a sidewall of the MTJ structure. A word line is connected with the MTJ structure, and a bit line is connected with one of top and bottom surfaces of the MTJ structure. A capacitor is connected with one of top and bottom surfaces of the MTJ structure that is not connected with the bit line. Current leakage in the DRAM device is reduced and a unit cells may be vertically stacked on the substrate, so a smaller surface area of the substrate is required for the DRAM device.

Abstract: A trench structure, a method of forming the trench structure, a memory cell using the trench structure and a method of forming a memory cell using the trench structure. The trench structure includes: a substrate; a trench having contiguous upper, middle and lower regions, the trench extending from a top surface of said substrate into said substrate; the upper region of the trench having a vertical sidewall profile; and the middle region of the trench having a tapered sidewall profile.

Abstract: A trench capacitor is filled with a set of two or more storage plates by consecutively depositing layers of dielectric and conductor and making contact to the ground plates by etching an aperture through the plates to the buried plate in the substrate and connecting the one or more ground plate to the substrate; the charge storage plates are connected at the top of the capacitor by blocking the end of the first plate during the formation of the second ground plate and exposing the material of the first storage plate during deposition of the second storage plate.

Abstract: An embodiment relates generally to a method of forming a capacitor. The method includes depositing a first layer of polysilicon on a substrate and implanting a high dose of implant into the first layer of polysilicon. The method also includes depositing a layer of dielectric over the first layer of polysilicon and depositing a second layer of polysilicon over the layer of dielectric. The method further includes implanting an equivalent concentration of implant in both the first layer of polysilicon into the second layer of polysilicon.

Abstract: A MOS varactor includes a shallow PN junction beneath the surface of the substrate of a MOS structure. In depletion mode, the depletion region of the MOS structure merges with the depletion region of the shallow PN junction. This increases the total width of the depletion region of the MOS varactor to reduce Cmin.

Abstract: In a nonvolatile semiconductor memory device including a memory cell column formed by connecting in series a plurality of memory cells each having a structure in which a charge-storage layer and a control gate are stacked via an insulating layer on a semiconductor substrate, a first selection transistor formed on the semiconductor substrate and connected between one end of the memory cell column and a common source line, and a second selection transistor formed on the semiconductor substrate and connected between the other end of the memory cell column and a bit line, a recessed portion is formed on a surface of the semiconductor substrate between the first selection transistor and a memory cell adjacent to the first selection transistor, and an edge at a side of the first selection transistor in the recessed portion reaches an end portion at a side of the memory cell in a gate of the first selection transistor.

Abstract: Methods of forming a memory device include forming a device isolation layer in a semiconductor substrate including a cell array region and a resistor region, the device isolation layer extending into the resistor region and defining an active region in the semiconductor substrate. A first conductive layer is formed on the device isolation layer in the resistor region. The semiconductor substrate is exposed in the cell array region. A cell insulation layer is formed on a portion of the semiconductor substrate including the exposed cell array region, the active region and the device isolation layer in the resistor region. A second conductive layer is formed on the cell insulation layer in the portion of the semiconductor substrate including the exposed cell array region, the active region and the device isolation layer in the resistor region.

Abstract: A non-volatile memory array includes a semiconductor substrate having a main surface, a first source/drain region and a second source/drain region. The second source/drain region is spaced apart from the first source/drain region. A well region is disposed in a portion of the semiconductor substrate between the first source/drain region and the second source/drain region. A plurality of memory cells are disposed on the main surface above the well region. Each memory cell includes a first oxide layer formed on the main surface of the substrate, a charge storage layer disposed above the blocking oxide layer relative to the main surface of the semiconductor substrate and second oxide layer disposed above the charge storage layer relative to the main surface of the semiconductor substrate. A plurality of wordlines are disposed above the second oxide layer relative to the main surface of the semiconductor substrate.

Abstract: A method of manufacturing a semiconductor device includes forming a plurality of gate electrodes for a plurality of memory cell transistors on a surface of a semiconductor substrate, each gate electrode including a polycrystalline layer on an upper portion thereof; filling a first silicon oxide film between the plurality of gate electrodes; exposing the polycrystalline layers; depositing a metal layer on the polycrystalline layers; alloying the metal layer with the polycrystalline layers to form silicide layers and removing a remainder metal layer unused as the silicide layer; forming a second silicon oxide film on and between the gate electrodes, an upper surface of the second silicon oxide film being higher than an upper surface of the gate electrode in regions over the gate electrodes and regions between the gate electrodes; and forming a silicon nitride film on the second silicon oxide film.

Abstract: Methods for nanopatterning and methods for production of nanoparticles utilizing such nanopatterning are described herein. In exemplary embodiments, masking nanoparticles are disposed on various substrates and to form a nanopatterned mask. Using various etching and filling techniques, nanoparticles and nanocavities can be formed using the masking nanoparticles and methods described throughout.

Abstract: In a method for fabricating a semiconductor memory device and a semiconductor memory device fabricated by the method, the method includes forming a multi-layered dielectric structure including a first dielectric layer with an ion implantation layer and a second dielectric layer without an ion implantation layer, over a semiconductor substrate; forming nanocrystals in the first and second dielectric layers by diffusing ions of the ion implantation layer by thermally treating the multi-layered dielectric structure; and forming a gate electrode on the multi-layered dielectric structure.

Abstract: A charge trap flash memory device and method of making same are provided. The device includes: a tunnel insulating layer, a charge trap layer; a blocking insulating layer; and a gate electrode sequentially formed on a substrate. The charge trap layer includes: plural trap layers comprising a first material having a first band gap energy level; spaced apart nanodots, each nanodot being at least partially surrounded by at least one of the trap layers, wherein the nanodots comprise a second material having a second band gap energy level that is lower than the first band gap energy level; and an intermediate blocking layer comprising a third material having a third band gap energy level that is higher than the first band gap energy level, formed between at least two of the trap layers. This structure prevents loss of charges from the charge trap layer and improves charge storage capacity.

Abstract: A power semiconductor device includes: a first semiconductor layer; a second semiconductor layer and a third semiconductor layer provided in an upper portion of the first semiconductor layer and alternately arranged parallel to an upper surface of the first semiconductor layer; a plurality of fourth semiconductor layers provided on the third semiconductor layer; a fifth semiconductor layer selectively formed in an upper surface of each of the fourth semiconductor layers; a control electrode; a gate insulating film; a first main electrode provided on a lower surface of the first semiconductor layer; and a second main electrode provided on the fourth and the fifth semiconductor layers.

Abstract: An apparatus is disclosed to increase a breakdown voltage of a semiconductor device. The semiconductor device includes a first heavily doped region to represent a source region. A second heavily doped region represents a drain region of the semiconductor device. A third heavily doped region represents a gate region of the semiconductor device. The semiconductor device further includes a shallow trench isolation (STI) region to increase the resistance from the drain region to the source region. The STI region includes a first side vertically aligned with a second side of the gate region. The STI region extends from the first side to a second side in contact with a second side of the drain region. The breakdown voltage of the n-type semiconductor device is directly proportional to a vertical length, or a depth, of the first side and/or the second side of the STI region.

Abstract: A trench metal-oxide-semiconductor field effect transistor (MOSFET), in accordance with one embodiment, includes a drain region, a plurality of gate regions disposed above the drain region, a plurality of gate insulator regions each disposed about a periphery of a respective one of the plurality of gate regions, a plurality of source regions disposed in recessed mesas between the plurality of gate insulator regions, a plurality of body regions disposed in recessed mesas between the plurality of gate insulator regions and between the plurality of source regions and the drain region.

Abstract: A semiconductor power device includes trenched semiconductor power device comprising a trenched gate surrounded by a source region encompassed in a body region above a drain region disposed on a bottom surface of a substrate. The semiconductor power device further includes an insulation layer covering the trenched semiconductor power device with a source-body contact trench opened therethrough the source and body regions and extending into an epitaxial layer below the body regions and filled with contact metal plug therein. The semiconductor power device further includes an embedded Schottky diode disposed near a bottom of the source-body contact trench below the contact metal plug wherein the Schottky diode further includes a Schottky barrier layer having a barrier height for reducing a leakage current through the embedded Schottky diode during a reverse bias between the drain and the source.

Abstract: A high-voltage metal-oxide-semiconductor (HVMOS) device having increased breakdown voltage and methods for forming the same are provided. The HVMOS device includes a semiconductor substrate; a gate dielectric on a surface of the semiconductor substrate; a gate electrode on the gate dielectric; a source/drain region adjacent and horizontally spaced apart from the gate electrode; and a recess in the semiconductor substrate and filled with a dielectric material. The recess is between the gate electrode and the source/drain region, and is horizontally spaced apart from the gate electrode.

Abstract: A power semiconductor device includes: a first semiconductor substrate; a second semiconductor layer; a plurality of third semiconductor pillar regions and a plurality of fourth semiconductor pillar regions that are provided in an upper layer of the second semiconductor layer and alternatively arranged along a direction parallel to an upper surface of the first semiconductor substrate; a first main electrode; and a second main electrode. A concentration of first-conductivity-type impurity in a connective portion between the second semiconductor layer and the third semiconductor pillar regions is lower than concentrations of first-conductivity-type impurity in portions of both sides of the connective portion in a direction from the second semiconductor layer to the third semiconductor pillar regions.

Abstract: A power semiconductor device includes: a first semiconductor layer; a second semiconductor layer and a third semiconductor layer that are provided above the first semiconductor layer and alternatively arranged along a direction parallel to an upper surface of the first semiconductor layer; a plurality of fourth semiconductor layers provided on some of immediately upper regions of the third semiconductor layers and connected to the third semiconductor layer; a fifth semiconductor layer; a control electrode; a gate insulating film; a first main electrode; and a second main electrode. An array period of the fourth semiconductor layers is larger than an array period of the second semiconductor layers. A thickness of a part of the gate insulating film disposed in an immediate upper region of a central portion between the fourth semiconductor layers is thicker than a thickness of a part of the gate insulating film disposed in the immediate upper region of the fourth semiconductor layer.

Abstract: A laterally diffused metal-oxide-semiconductor transistor device includes a substrate having a first conductivity type with a semiconductor layer formed over the substrate. A source region and a drain extension region of the first conductivity type are formed in the semiconductor layer. A body region of a second conductivity type is formed in the semiconductor layer. A conductive gate is formed over a gate dielectric layer that is formed over a channel region. A drain contact electrically connects the drain extension region to the substrate and is laterally spaced from the channel region. The drain contact includes a highly-doped drain contact region formed between the substrate and the drain extension region in the semiconductor layer, wherein a topmost portion of the highly-doped drain contact region is spaced from the upper surface of the semiconductor layer. A source contact electrically connects the source region to the body region.

Abstract: The invention is related to a MOS transistor and its fabrication method to reduce short-channel effects. Existing process has the problem of high complexity and high cost to reduce short-channel effects by using epitaxial technique to produce an elevated source and drain structure. In the invention, the MOS transistor, fabricated on a silicon substrate after an isolation module is finished, includes a gate stack, a gate sidewall spacer, and source and drain areas. The silicon substrate has a groove and the gate stack is formed in the groove.

Abstract: A recessed-gate thin-film transistor (RG-TFT) with a self-aligned lightly doped drain (LDD) is provided, along with a corresponding fabrication method. The method deposits an insulator overlying a substrate and etches a trench in the insulator. The trench has a bottom and sidewalls. An active silicon (Si) layer is formed overlying the insulator and trench, with a gate oxide layer over the active Si layer. A recessed gate electrode is then formed in the trench. The TFT is doped and LDD regions are formed in the active Si layer overlying the trench sidewalls. The LDD regions have a length that extends from a top of the trench sidewall, to the trench bottom, with a doping density that decreases in response to the LDD length. Alternately stated, the LDD length is directly related to the depth of the trench.

Abstract: Disclosed is a method of manufacturing a thin film transistor, in which a semiconductor layer and a gate insulating film may be formed through ink jet printing using a single bank, thereby simplifying the manufacturing process and decreasing the manufacturing cost, leading to more economical thin film transistors. The thin film transistor manufactured using the method of example embodiments may be used as a switching element for sensors, memory devices, optical devices, and active matrix flat panel displays.

Abstract: A double-gate transistor having front (upper) and back gates that are aligned laterally is provided. The double-gate transistor includes a back gate thermal oxide layer below a device layer; a back gate electrode below a back gate thermal oxide layer; a front gate thermal oxide above the device layer; a front gate electrode layer above the front gate thermal oxide and vertically aligned with the back gate electrode; and a transistor body disposed above the back gate thermal oxide layer, symmetric with the first gate. The back gate electrode has a layer of oxide formed below the transistor body and on either side of a central portion of the back gate electrode, thereby positioning the back gate self-aligned with the front gate. The transistor also includes source and drain electrodes on opposite sides of said transistor body.

Abstract: A semiconductor integrated circuit device capable of suppressing variations in transistor characteristics due to the well proximity effect is provided. Standard cell rows are arranged in a vertical direction, each standard cell row including standard cells arranged in a horizontal direction. In the standard cell rows, positions of the N well and the P region in the vertical direction are switched every other row. Adjacent standard cell rows share the P region or the N well. A distance from a PMOS transistor located at an end of a standard cell row to an end of an N well is greater than or equal to a width of an N well shared by standard cell rows.

Abstract: A semiconductor device with a strain layer and a method of fabricating the semiconductor device with a strain layer that can reduce a loading effect are provided. By arranging active dummies and gate dummies not to overlap each other, the area of active dummy on which a strain layer dummy will be formed can be secured, thereby reducing the loading effect.

Abstract: Disclosed is a method of fabricating a field effect transistor. In the method, a gate stack on a top surface of a semiconductor substrate is formed, and then a first spacer is formed on a sidewall of the gate stack. Next, a silicide self-aligned to the first spacer is deposited in/or on the semiconductor substrate. Subsequently a second spacer covering the surface of the first spacer, and a contact liner over at least the gate stack, the second spacer and the silicide, are formed. Then an interlayer dielectric over the contact liner is deposited. Next, a metal contact opening is formed to expose the contact liner over the silicide. Finally, the opening is extended through the contact liner to expose the silicide without exposing the substrate.

Abstract: A semiconductor device includes a semiconductor substrate; a gate dielectric layer disposed on the semiconductor substrate; a gate conductive layer doped with impurities selected from nitrogen, carbon, silicon, germanium, fluorine, oxygen, helium, neon, xenon or a combination thereof on the gate dielectric layer; and source/drain doped regions formed adjacent to the gate conductive layer in the semiconductor substrate, wherein the source and drain doped regions are substantially free of the impurities doped into the gate conductive layer. These impurities reduce the diffusion rates of the N-type of P-type dopants in the gate conductive layer, thereby improving the device performance.

Abstract: An ambipolar transistor, including a p-type semiconductor region and an n-type semiconductor region near the p-type semiconductor region. Also a first terminal and second terminal contact both the p-type semiconductor region and the n-type semiconductor region. Furthermore, the p-type semiconductor region and the n-type semiconductor region substantially do not overlap each other. A method of manufacturing an ambipolar transistor is also disclosed, including forming a p-type semiconductor region, forming an n-type semiconductor region near the p-type semiconductor region, forming a first terminal contacting both the p-type semiconductor region and n-type semiconductor region, forming a second terminal contacting both the p-type semiconductor region and n-type semiconductor region; and wherein the p-type semiconductor region and the n-type semiconductor region substantially do not overlap, and have substantially no interfacial area.

Abstract: A semiconductor device includes a substrate, a plurality of first columns having a first conductivity type, a plurality of second columns having a second conductivity type, a first electrode, and a second electrode. The first columns and the second columns are alternately arranged on the substrate to provide a super junction structure. The first electrode is disposed on the super junction structure, forms schottky junctions with the first columns, and forms ohmic junctions with the second columns. The second electrode is disposed on the substrate on an opposite side of the super junction structure. At least a part of the substrate and the super junction structure has lattice defects to provide a lifetime control region at which a lifetime of a minority carrier is controlled to be short.