Abstract: A method of forming a p-type compound semiconductor layer includes increasing a temperature of a substrate loaded into a reaction chamber to a first temperature. A source gas of a Group III element, a source gas of a p-type impurity, and a source gas of nitrogen containing hydrogen are supplied into the reaction chamber to grow the p-type compound semiconductor layer. Then, the supply of the source gas of the Group III element and the source gas of the p-type impurity is stopped and the temperature of the substrate is lowered to a second temperature. The supply of the source gas of nitrogen containing hydrogen is stopped and drawn out at the second temperature, and the temperature of the substrate is lowered to room temperature using a cooling gas. Accordingly, hydrogen is prevented from bonding to the p-type impurity in the p-type compound semiconductor layer.

Abstract: The present invention is directed to systems and methods for nanowire growth. In an embodiment, methods for nanowire growth and doping are provided, including methods for epitaxial vertically oriented nanowire growth including providing a substrate material having one or more nucleating particles deposited thereon in a reaction chamber, introducing an etchant gas into the reaction chamber at a first temperature which gas aids in cleaning the surface of the substrate material, contacting the nucleating particles with at least a first precursor gas to initiate nanowire growth, and heating the alloy droplet to a second temperature, whereby nanowires are grown at the site of the nucleating particles. The etchant gas may also be introduced into the reaction chamber during growth of the wires to provide nanowires with low taper.

Abstract: The present invention relates to a method for producing an n-type ZnTe system compound semiconductor single crystal having high carrier concentration and low resistivity, the ZnTe system compound semiconductor single crystal, and a semiconductor device produced by using the ZnTe system compound semiconductor as a base member. Concretely, a first dopant and a second dopant are co-doped into the ZnTe system compound semiconductor single crystal so that the number of atoms of the second dopant becomes smaller than the number of atoms of the first dopant, the first dopant being for controlling a conductivity type of the ZnTe system compound semiconductor to a first conductivity type, and the second dopant being for controlling the conductivity type to a second conductivity type different from the first conductivity type. By the present invention, a desired carrier concentration can be achieved with a doping amount smaller than in earlier technology, and crystallinity of the obtained crystal can be improved.

Abstract: The present invention relates to a method for producing an n-type ZnTe system compound semiconductor single crystal having high carrier concentration and low resistivity, the ZnTe system compound semiconductor single crystal, and a semiconductor device produced by using the ZnTe system compound semiconductor as a base member. Concretely, a first dopant and a second dopant are co-doped into the ZnTe system compound semiconductor single crystal so that the number of atoms of the second dopant becomes smaller than the number of atoms of the first dopant, the first dopant being for controlling a conductivity type of the ZnTe system compound semiconductor to a first conductivity type, and the second dopant being for controlling the conductivity type to a second conductivity type different from the first conductivity type. By the present invention, a desired carrier concentration can be achieved with a doping amount smaller than in earlier technology, and crystallinity of the obtained crystal can be improved.

Abstract: A base structure for high performance Silicon Germanium (SiGe) based heterojunction bipolar transistors (HBTs) with arsenic atomic layer doping (ALD) is disclosed. The ALD process subjects the base substrate to nitrogen gas or hydrogen gas (in ambient temperature approximately equal to 500 degrees Celsius) and provides an additional SiGe spacer layer. The surface of the final silicon cap layer is preferably etched to remove most of the arsenic. The resulting SiGe HBT with an arsenic ALD layer is less sensitive to process temperature and exposure times, and exhibits lower dopant segregation and sharper base profiles.

Abstract: A method of producing a GaN crystal is directed to growing a GaN crystal on a GaN seed crystal substrate. The method includes the steps of preparing a GaN seed crystal substrate including a first dopant such that the thermal expansion coefficient of the GaN seed crystal substrate becomes greater than that of the GaN crystal, and growing the GaN crystal to a thickness of at least 1 mm on the GaN seed crystal substrate. Accordingly, there can be provided a method of producing a GaN crystal that can suppress generation of a crack and grow a thick GaN crystal, and a GaN crystal substrate.

Abstract: A semiconductor wafer is formed of a substrate wafer of single crystal silicon doped with dopant atoms of the n type or p type, with a front surface and a back surface, contains a layer deposited epitaxially on the front surface of the substrate wafer. The substrate wafer additionally includes an n++ or p++ doped layer, which extends from the front surface of the substrate wafer into the substrate wafer and has a defined thickness. The semiconductor wafer is produced by a process in which dopant atoms of the n type or p type are introduced into the substrate wafer through the front surface of the substrate wafer, the dopant concentration in a layer which extends from the front surface of the substrate wafer into the substrate wafer being increased from the level n+ or p+ to the level n++ or p++, and an epitaxial layer is then deposited on this layer.

Abstract: Formation of carbon-substituted single crystal silicon layer is prone to generation of large number of defects especially at high carbon concentration. The present invention provides structures and methods for providing low defect carbon-substituted single crystal silicon layer even for high concentration of carbon in the silicon. According to the present invention, the active retrograde profile in the carbon implantation reduces the defect density in the carbon-substituted single crystal silicon layer obtained after a solid phase epitaxy. This enables the formation of semiconductor structures with compressive stress and low defect density. When applied to semiconductor transistors, the present invention enables N-type field effect transistors with enhanced electron mobility through the tensile stress that is present into the channel.

Abstract: In one embodiment the present invention is a method of conducting multiple step multiple chamber chemical vapor deposition while avoiding reactant memory in the relevant reaction chambers. The method includes depositing a layer of semiconductor material on a substrate using vapor deposition in a first deposition chamber followed by evacuation of the growth chamber to reduce vapor deposition source gases remaining in the first deposition chamber after the deposition growth and prior to opening the chamber. The substrate is transferred to a second deposition chamber while isolating the first deposition chamber from the second deposition chamber to prevent reactants present in the first chamber from affecting deposition in the second chamber and while maintaining an ambient that minimizes or eliminates growth stop effects. After the transferring step, an additional layer of a different semiconductor material is deposited on the first deposited layer in the second chamber using vapor deposition.

Abstract: In one embodiment, a method of fabricating a transistor for a memory cell includes the steps of performing a counter doping implant before or after a source/drain implant. The counter doping implant may comprise one or more implant steps that move a metallurgical junction formed by a well and a highly doped region closer to a surface of the substrate. The counter doping implant may also increase the concentration of the dopant of the well. The counter doping implant and the source/drain implant may be performed using the same mask. Transistors fabricated using embodiments of the present invention may be employed in memory cells to reduce soft error rates.

Abstract: A plurality of successive layers are firmly adhered to one another and to a wafer surface and an electrical component or sub-assembly even when the wafer surface is not even and the layers are bent. The wafer surface is initially cleaned by an ion bombardment of an inert gas (e.g. argon) on the wafer surface in an RF discharge at a relatively high gas pressure. The wafer surface is then provided with a microscopic roughness by applying a low power so that the inert gas (e.g. argon) ions do not have sufficient energy to etch the surface. A layer of chromium is then sputter deposited on the wafer surface as by a DC magnetron with an intrinsic tensile stress and low gas entrapment by passing a minimal amount of the inert gas through the magnetron and by applying no RF bias to the wafer. The chromium layer is atomically bonded to the microscopically rough wafer surface.

Abstract: A method of manufacturing a ridge type semiconductor light emitting device includes: a process of epitaxially growing a multi-layered semiconductor layer having at least a first conductive type cladding layer, an active layer, a second conductive type first cladding layer, an etching stop layer, and a second conductive type second cladding layer on a substrate; a process of forming a ridge groove for forming a ridge; and a process of forming a current-flow barrier layer in the ridge groove. The process of forming ridge grooves has first and second anisotropic etching processes of performing anisotropic etching, an etching-mask forming process, and an isotropic etching process of performing anisotropic etching.

Abstract: The present invention is characterized in that a semiconductor film containing a rare gas element is formed on a crystalline semiconductor film obtained by using a catalytic element via a barrier layer, and the catalytic element is moved from the crystalline semiconductor film to the semiconductor film containing a rare gas element by a heat treatment. Furthermore, a first impurity region and a second impurity region formed in a semiconductor layer of a first n-channel TFT are provided outside a gate electrode. A third impurity region formed in a semiconductor layer of a second n-channel TFT is provided so as to be partially overlapped with a gate electrode. A third impurity region is provided outside a gate electrode. A fourth impurity region formed in a semiconductor layer of a p-channel TFT is provided so as to be partially overlapped with a gate electrode. A fifth impurity region is provided outside a gate electrode.

Abstract: A method to achieve controlled conductivity in microfluidic devices, and a device formed thereby. The method comprises forming a microchannel or a well in an insulating material, and ion implanting at least one region of the insulating material at or adjacent the microchannel or well to increase conductivity of the region.

Abstract: Methods for fabricating facetless semiconductor structures using commercially available chemical vapor deposition systems are disclosed herein. A key aspect of the invention includes selectively depositing an epitaxial layer of at least one semiconductor material on the semiconductor substrate while in situ doping the epitaxial layer to suppress facet formation. Suppression of faceting during selective epitaxial growth by in situ doping of the epitaxial layer at a predetermined level rather than by manipulating spacer composition and geometry alleviates the stringent requirements on the device design and increases tolerance to variability during the spacer fabrication.

Abstract: The invention relates to a method and device for depositing several crystalline semiconductor layers on at least one semiconductor crystalline substrate. According to said method, gaseous parent substances are introduced into a process chamber of a reactor by means of a gas inlet organ, said substances accumulating, optionally after a chemical gas phase and/or surface reaction, on the surface of a semiconductor substrate that is placed on a substrate holder in the process chamber, thus forming the semiconductor layer. Said semiconductor layer and the semiconductor substrate form a crystal consisting of either one or several elements from main group V, elements from main groups III and V, or elements from main groups II and VI.

Abstract: A multi-point calibration standards and a method of fabricating calibration standards which are used to quantify the dose or concentration of a dopant or impurity in a silicon matrix. The calibration standards include a set of calibration standard wafers for each dopant or impurity to be quantified. On each calibration standard wafer in the set is provided a silicon matrix incorporated with one of various concentrations, by weight, of the dopant or impurity in the silicon. The atomic concentration of the dopant or impurity in the silicon on each wafer in the set is measured. A calibration curve is then prepared in which the silicon/dopant or silicon/impurity ratio on each calibration standard wafer in the set is plotted versus the atomic concentration of the dopant or impurity in the silicon on the wafer.

Abstract: A method of depositing a p-type magnesium-, cadmium- and/or zinc-oxide-based II-VI Group compound semiconductor crystal layer over a substrate by a metalorganic chemical vapor deposition technique. A reaction gas is supplied to a surface of a heated substrate in a direction parallel or oblique to the substrate. The p-type magnesium-, cadmium- and/or zinc-oxide-based II-VI Group compound semiconductor crystal layer is grown on the heated substrate, while introducing a pressing gas substantially in a vertical direction toward the substrate to press the reaction gas against the entire surface of the substrate.

Abstract: The present invention provides a method of manufacturing a semiconductor device, in which while a conductive layer is formed on an oxide film formed as an insulating layer by using a CVD method, oxygen deficiency of the oxide film can be avoided without any drop in an dielectric breakdown resistance as the insulating layer of the oxide film and without any reduction in a long-term reliability. In this manufacturing method, when the conductive layer as a gate electrode is formed on the oxide film formed as a gate insulating layer, the conductive layer is formed in a non-reducing atmosphere.

Abstract: A wafer bumping method comprising the following steps of. A wafer having fields is provided. The wafer having at least one wafer identification character formed thereon within one or more of the fields. A dry film resist is formed over the wafer. Portions of the dry film resist are selectively exposed field by field using a mask whereby the mask is shifted over the one or more fields containing the at least one wafer identification character so that the one or more fields containing the at least one wafer identification character is double exposed after the mask shift so that all of the one or more fields containing the at least one wafer identification character is completely exposed. The selectively exposed dry film resist is developed to remove the non-exposed portions of the dry film resist.

Abstract: It is an object of the invention to provide a semiconductor wafer obtained by forming a semiconductor thin film with uniform resistivity on a main surface of a semiconductor single crystal substrate of 300 mm or more in diameter. When a process gas is supplied to over a main surface of a silicon single crystal substrate 12 in rotation in almost parallel to the main surface thereof in one direction in a reaction chamber 10 through six inlet ports 18a to 18f disposed in width direction of the reaction chamber 10, H2 gas, a semiconductor raw material gas and a dopant gas are supplied onto an area in the vicinity of the center of the main surface of the silicon single crystal substrate 12 and an intermediate area thereof through the inner inlet ports 18a and 18b and the middle inlet ports 18c and 18d, and only H2 gas and the semiconductor raw material gas without the dopant gas are supplied onto an area in the vicinity of the outer periphery thereof from the outer inlet ports 18e and 18f.

Abstract: A highly reliable semiconductor laser device having a low operating voltage is obtained by increasing adhesive force of the overall electrode layer to a nitride-based semiconductor layer without deteriorating a low contact property. This nitride-based semiconductor laser device comprises a nitride-based semiconductor layer formed on an active layer and an electrode layer formed on the nitride-based semiconductor layer, while the electrode layer includes a first electrode layer containing a material having strong adhesive force to the nitride-based semiconductor layer and a second electrode layer, formed on the first electrode layer, having weaker adhesive force to the nitride-based semiconductor layer than the first electrode layer for reducing contact resistance of the electrode layer with respect to the nitride-based semiconductor layer.

Abstract: A method for activating implanted dopants in a semiconductor substrate to form shallow junctions comprises the steps of: maintaining gas pressure in the processing chamber at a level significantly lower than atmospheric pressure, providing a flow of a carrier gas into the processing chamber, subjecting the substrate to a temperature treatment process, and introducing oxygen into the processing chamber during all or part of the temperature treatment process.

Abstract: Methods of forming metal-doped chalcogenide layers and devices containing such doped chalcogenide layers include using a plasma to induce diffusion of metal into a chalcogenide layer concurrently with metal deposition. The plasma contains at least one noble gas of low atomic weight, such as neon or helium. The plasma has a sputter yield sufficient to sputter a metal target and a UV component of its emitted spectrum sufficient to induce diffusion of the sputtered metal into the chalcogenide layer. Using such methods, a conductive layer can be formed on the doped chalcogenide layer in situ. In integrated circuit devices, such as non-volatile chalcogenide memory devices, doping of the chalcogenide layer concurrently with metal deposition and formation of a conductive layer in situ with the doping of the chalcogenide layer reduces contamination concerns and physical damage resulting from moving the device substrate from tool to tool, thus facilitating improved device reliability.

Abstract: The present invention provides a method of manufacturing a semiconductor device, in which while a conductive layer is formed on an oxide film formed as an insulating layer by using a CVD method, oxygen deficiency of the oxide film can be avoided without any drop in an dielectric breakdown resistance as the insulating layer of the oxide film and without any reduction in a long-term reliability. In this manufacturing method, when the conductive layer as a gate electrode is formed on the oxide film formed as a gate insulating layer, the conductive layer is formed in a non-reducing atmosphere.

Abstract: A method for fabricating p-type, i-type, and n-type III-V compound materials using HVPE techniques is provided. If desired, these materials can be grown directly onto the surface of a substrate without the inclusion of a low temperature buffer layer. By growing multiple layers of differing conductivity, a variety of different device structures can be fabricated including simple p-n homojunction and heterojunction structures as well as more complex structures in which the p-n junction, either homojunction or heterojunction, is interposed between a pair of wide band gap material layers. The provided method can also be used to fabricate a device in which a non-continuous quantum dot layer is grown within the p-n junction. The quantum dot layer is comprised of a plurality of quantum dot regions, each of which is typically between approximately 20 and 30 Angstroms per axis.

Abstract: The present invention provides a semiconductor device, a method of manufacture therefor, and an integrated circuit including the same. The semiconductor device may include a doped buried layer located over a doped substrate and a doped epitaxial layer located over the doped buried layer. The semiconductor device may further include a first doped lattice matching layer located between the substrate and the buried layer and a second doped lattice matching layer located between the doped buried layer and the doped epitaxial layer.

Abstract: An improved atomic layer doping apparatus is disclosed as having multiple doping regions in which individual monolayer species are first deposited and then dopant atoms contained therein are diffused into the substrate. Each doping region is chemically separated from adjacent doping regions. A loading assembly is programmed to follow pre-defined transfer sequences for moving semiconductor substrates into and out of the respective adjacent doping regions. According to the number of doping regions provided, a plurality of substrates could be simultaneously processed and run through the cycle of doping regions until a desired doping profile is obtained.

Abstract: A phosphor in the form of a columnar powder capable of exhibiting enhanced luminous efficiency, providing various luminous colors by electron excitation depending on the selection of elements added thereto and having improved life characteristics. The phosphor is made by heating a starting material constituted by a GaN based phosphor material to a temperature equal to or greater than a sublimation temperature thereof. The phosphor thus obtained is represented by Ga1−xInxN:A,B, wherein x is larger than or equal to 0 and smaller than 1 (0≦x<1), A is Zn or Mg, and B is Si or Ge.

Abstract: A quantum computer comprises a pair of qubits disposed between first and second single-electron electrometers and a control gate. The qubits each comprise a molecule of ammonia caged inside a C60 molecule disposed on a substrate. The ammonia-bearing C60 molecule is positioned using a scanning probe microscope.

Abstract: Compound semiconductor material is irradiated with x-ray radiation to activate a dopant material. Active carrier concentration efficiency may be improved over known methods, including conventional thermal annealing. The method may be employed for III-V group compounds, including GaN-based semiconductors, doped with p-type material to form low resistivity p-GaN. The method may be further employed to manufacture GaN-based LEDs, including blue LEDs, having improved forward bias voltage and light-emitting efficiency.

Abstract: A p-type zinc oxide film and a process for preparing the film is disclosed. In a preferred embodiment, the p-type zinc oxide film contains arsenic and is grown on a gallium arsenide substrate. The p-type zinc oxide film has a net acceptor concentration of at least about 1015 acceptors/cm3, a resistivity of no greater than about 1 ohm-cm, and a Hall mobility of between about 0.1 and about 50 cm2/Vs.

Abstract: It is an object of the invention to provide a semiconductor wafer obtained by forming a semiconductor thin film with uniform resistivity on a main surface of a semiconductor single crystal substrate of 300 mm or more in diameter. When a process gas is supplied to over a main surface of a silicon single crystal substrate 12 in rotation in almost parallel to the main surface thereof in one direction in a reaction chamber 10 through six inlet ports 18a to 18f disposed in width direction of the reaction chamber 10, H2 gas, a semiconductor raw material gas and a dopant gas are supplied onto an area in the vicinity of the center of the main surface of the silicon single crystal substrate 12 and an intermediate area thereof through the inner inlet ports 18a and 18b and the middle inlet ports 18c and 18d, and only H2 gas and the semiconductor raw material gas without the dopant gas are supplied onto an area in the vicinity of the outer periphery thereof from the outer inlet ports 18e and 18f.

Abstract: A membrane of the micromechanical semiconductor configuration is formed within a cavity. The membrane is formed by a crystalline layer within the substrate or within an epitaxial sequence of layers of the semiconductor configuration arranged on a substrate. The membrane is laid at the edge region on a support and is covered over by a covering layer supported on a counter-support. The support and the counter-support have a different etch rate from the membrane. Wet-chemical etching of the layer sequence with an etchant that is selective to the material of the membrane thus leads to the formation of a cavity around the membrane. Preferably, the layers are formed of differently doped materials.

Abstract: A method for fabricating p-type, i-type, and n-type III-V compound materials using HVPE techniques is provided. If desired, these materials can be grown directly onto the surface of a substrate without the inclusion of a low temperature buffer layer. By growing multiple layers of differing conductivity, a variety of different device structures can be fabricated including simple p-n homojunction and heterojunction structures as well as more complex structures in which the p-n junction, either homojunction or heterojunction, is interposed between a pair of wide band gap material layers. The provided method can also be used to fabricate a device in which a non-continuous quantum dot layer is grown within the p-n junction. The quantum dot layer is comprised of a plurality of quantum dot regions, each of which is typically between approximately 20 and 30 Angstroms per axis.

Abstract: In a method of manufacturing a silicon carbide substance, such as a film, a layer, a semiconductor, which is doped with an impurity, a carbonization process is executed after formation of a doped silicon substance which is obtained by carrying out a silicon deposition process and by a doping process of the impurity. Both the silicon deposition and the doping processes may be simultaneously or separately carried out prior to the carbonization process or may be continued during the carbonization process also. At any rate, the carbonization process is intermittently carried out. A unit process of composed of a combination of the silicon deposition process, the doping process, and the carbonization process may be repeated a plurality times, for example, 2000 times.

Abstract: A layer configuration includes a material layer and a diffusion barrier which blocks diffusing material components. The barrier is disposed in the vicinity of a layer boundary of the material layer and is formed predominantly in grain boundaries of the material layer. A process for producing a diffusion barrier is also provided.

Abstract: A method for preparing a gallium nitride phosphor which is capable of emitting light at luminance increased to a degree sufficient to permit the phosphor to be practically used. A dopant compound containing elements reacted with H2 and gasified by heating is arranged on an upstream side in a calcination oven in which NH3 is flowed and a matrix element compound is arranged on the downstream side therein, resulting in calcination of the compound being carried out. This permits GaN to be surrounded with ammonia and the dopant during the calcination, so that the GaN phosphor may be fully doped with the dopant.

Abstract: A method for forming a plurality of buried layers inside a semiconductor device is disclosed. The method includes the following steps. Firstly, a semiconductor substrate is provided. Then, the first type p+-type ions are implanted into the semiconductor substrate to form the p+-type region under the surface of semiconductor substrate. The semiconductor substrate is etched to form a plurality of concave portions and a plurality of convex portions using the first photoresist. The n+-type ions are second implanted into the semiconductor substrate as a plurality of n+-type region. Next, the oxide layer is deposited over the surface of the plurality of concave portions and the surface of the plurality of convex portions. The plurality of n+-type regions are heated to form as the buried layers. The oxide layer is removed. Finally, a silicon layer is formed to fill the plurality of concave of portions a silicon layer and to cover the surface of the plurality of convex portions.

Abstract: A method for fabricating a thin film transistor includes the steps of calculating a scan pitch of a laser beam such that an unevenly crystallized area and an evenly crystallized area of a crystallized polycrystalline silicon layer are alternately arranged at a regular interval, crystallizing an amorphous silicon layer to a polycrystalline silicon layer by scanning the laser beam according to the scan pitch, calculating a spacing pitch of active patterns from the scan pitch of the laser beam, and forming the active patterns in a selected portion of the polycrystalline silicon layer according to the spacing pitch.

Abstract: A gallium-nitride-based blue light emitting element that is manufacturable through a small number of processes and a method of manufacturing the same are disclosed. A first gallium-nitride-based semiconductor layer containing impurities of a first conductivity type, a gallium-nitridebased semiconductor active layer that is substantially intrinsic, and a second gallium-nitride-based semiconductor layer containing impurities of a second conductivity type that is opposite to the first conductivity type are formed according to a thermal CVD method and are left in an inert gas to cool by themselves.

Abstract: A process is disclosed for producing pn junctions and p-i-n junctions from group III nitride compound semiconductor materials. The process comprises growing of pn junctions and p-i-n junctions by hydride vapor phase epitaxy employing hydride of nitrogen (ammonia, hydrozine) as a source of nitrogen and halides of group III metal as a source of metal. Mg is used as acceptor impurity to form p-type III-V nitride layers. The preferred sources for Ga and Al are Ga and Al metals, respectively. The process is carried out in the temperature range from 900 to 1200° C.

Abstract: A method of depositing a material to a semiconductor device having a first mesa structure, a second mesa structure and a valley. Material is deposited from a first angular direction sufficient to substantially mask the valley with a first of the mesa structures and from a second angular direction sufficient to substantially mask the valley with the second mesa structure to form a first lip and a second lip on the respective first and second mesa structures overlying the valley and defining a space therebetween less than the width of the valley. Material is then deposited to the device from a third direction in substantial opposition to the device, the space operating to guide material deposition to the valley to provide discrete material deposition in the valley to form a discrete feature in the valley.

Abstract: A surface of a conductive member such as a gate electrode provided with a silicon layer is roughened. The roughened silicon layer is silicified so that its width is substantially increased, whereby phase transition of the silicide layer is simplified. Thus, the resistance of the refined silicide layer is reduced due to the simplified phase transition.

Abstract: A semiconductor processing method of providing a polysilicon layer atop a semiconductor wafer comprises the following sequential steps: a) depositing a first layer of arsenic atop a semiconductor wafer; b) depositing a second layer of silicon over the arsenic layer, the second layer having an outer surface; c) first annealing the wafer at a temperature of at least about 600.degree. C. for a time period sufficient to impart growth of polycrystalline silicon grains in the second layer and providing a predominately polysilicon second layer, the first annealing step imparting diffusion of arsenic within the second layer to promote growth of large polysilicon grains; and d) with the second layer outer surface being outwardly exposed, second annealing the wafer at a temperature effectively higher than the first annealing temperature for a time period sufficient to outgas arsenic from the polysilicon layer.

Abstract: A method of producing light-emitting porous silicon light-emitting diode including forming a porous silicon p+ layer in a p-type silicon wafer, annealing the wafer at 800-950.degree. C. in an atmosphere of inert gas and 1-25% oxygen, depositing a polycrystalline silicon film on the porous silicon layer, and n+ doping a portion of the polycrystalline silicon film.

Abstract: An oxide layer is thermally grown over a semiconductor body, and openings are etched in the oxide layer to expose portions of the surface of the semiconductor body. Then, epitaxial regions are grown from the semiconductor body into the openings in the oxide layer, which epitaxial regions will eventually become the active regions of devices.

Abstract: A method of manufacturing a semiconductor device, in which a pn-junction (2) is provided in a semiconductor wafer (1) of a first conduction type by providing doping atoms of a second conduction type, which is opposed to the first conduction type, via a first main face (3) of the main faces (3, 5) of the wafer (1), subdividing said wafer (1) into individual semiconductor bodies (10) having a pn-junction (2) between and substantially parallel to two opposing connection faces (3, 5), connecting said connection faces (3, 5) to connection bodies (11, 12) by means of a connection layer (15) and covering the semiconductor bodies (10) with a glass (20) A glass-covered semiconductor device is also described. After the pn-junction (2) has been provided on the first main face (3) of the semiconductor wafer (1), a monocrystalline silicon layer (7) having atoms of the second conduction type is epitaxially provided, whereafter the wafer (1) is subdivided into semiconductor bodies (10).

Abstract: A monocrystalline monolith contains a 3-D array of interconnected lattice-matched devices (which may be of one kind exclusively, or that kind in combination with one or more other kinds) performing digital, analog, image-processing, or neural-network functions, singly or in combination. Localized inclusions of lattice-matched metal and (or) insulator can exist in the monolith, but monolith-wide layers of insulator are avoided. The devices may be self-isolated, junction-isolated, or insulator-isolated, and may include but not be limited to MOSFETs, BJTs, JFETs, MFETs, CCDs, resistors, and capacitors. The monolith is fabricated in a single apparatus using a process such as MBE or sputter epitaxy executed in a continuous or quasicontinuous manner under automatic control, and supplanting hundreds of discrete steps with handling and storage steps interpolated.

Abstract: The invention relates to a method of manufacturing a semiconductor device with a pn junction, whereby an epitaxial layer (2) with a first zone (3) of a first conductivity type and with a second zone (4) of a second conductivity type opposed to the first is provided on a silicon substrate (1), a pn junction (5) being formed between the second and first zones (3, 4, respectively). According to the invention, the method is characterized in that the epitaxial layer (2) is provided by means of a CVD process at a temperature below 800.degree. C., the epitaxial layer (2) being provided in that first the first zone (3) and then the second zone (4) are epitaxially provided on the substrate (1), while no heat treatments at temperatures above 800.degree. C. take place after the epitaxial layer (2) has been provided.