Abstract: In one embodiment, a method for fabricating a III-Nitride transistor on a III-Nitride semiconductor body is disclosed. The method comprises etching dielectric trenches in a field dielectric overlying gate, source, and drain regions of the III-Nitride semiconductor body, and thereafter forming a gate dielectric over the gate, source and drain regions. The method further comprises forming a blanket diffusion barrier over the gate dielectric layer, and then removing respective portions of the blanket diffusion barrier from the source and drain regions. Thereafter, gate dielectric is removed from the source and drain regions to substantially expose the source and drain regions. Then, ohmic contacts are formed by depositing contact metal in the source and drain regions. The method results in highly conductive source/drain contacts that are particularly suitable for power transistors, for example, III-Nitride transistors, such as GaN transistors.

Abstract: Methods for protecting a texturized region and a lightly doped diffusion region of a solar cell to improve solar cell lifetime and efficiency are disclosed. In an embodiment, an example method includes providing a solar cell having a front side which faces the sun during normal operation and a back side opposite the front side, a silicon substrate and where the silicon substrate includes a texturized region and a lightly doped diffusion region. The method includes placing the solar cell on a receiving medium with the front side of the solar cell placed on an upper surface of the receiving medium, where the upper surface of the receiving medium prevents damage to the to the lightly doped diffusion region and damage to the texturized region on the front side of the solar cell during a contact printing process or transferring. In an embodiment, the lightly doped diffusion region has a doping concentration below 1×1019 cm?3 and the receiving medium includes a material having a moh's hardness in the range of 5-10.

Abstract: This invention provides methods that permit wafers to be loaded and unloaded in a gas-phase epitaxial growth chamber at high temperatures. Specifically, this invention provides a method for moving wafers or substrates that can bathe a substrate being moved in active gases that are optionally temperature controlled. The active gases can act to limit or prevent sublimation or decomposition of the wafer surface, and can be temperature controlled to limit or prevent thermal damage. Thereby, previously-necessary temperature ramping of growth chambers can be reduced or eliminated leading to improvement in wafer throughput and system efficiency.

Abstract: Field effect transistors fabricated using atomic layer doping processes are disclosed. In accordance with an embodiment of an atomic layer doping method, a semiconducting surface and a dopant gas mixture are prepared. Further, a dopant layer is grown on the semiconducting surface by applying the dopant gas mixture to the semiconducting surface under a pressure that is less than 500 Torr and a temperature that is between 300° C. and 750° C. The dopant layer includes at least 4×1020 active dopant atoms per cm3 that react with atoms on the semiconducting surface such that the reacted atoms increase the conductivity of the semiconducting surface.

Abstract: There is provided a method for manufacturing a semiconductor wafer, comprising: performing heating so that metals dissolve into semiconductors of the wafer to form a semiconductor-metal compound; and performing cooling so that the formed semiconductor-metal compound retrogradely melt to form a mixture of the metals and the semiconductors. According to embodiments of the present invention, it is possible to achieve wafers of a high purity applicable to the semiconductor manufacture.

Abstract: This invention provides apparatus, protocols, and methods that permit wafers to be loaded and unloaded in a gas-phase epitaxial growth chamber at high temperatures. Specifically, this invention provides a device for moving wafers or substrates that can bath a substrate being moved in active gases that are optionally temperature controlled. The active gases can act to limit or prevent sublimation or decomposition of the wafer surface, and can be temperature controlled to limit or prevent thermal damage. Thereby, previously-necessary temperature ramping of growth chambers can be reduced or eliminated leading to improvement in wafer throughput and system efficiency.

Abstract: A method for fabricating a metal-oxide semiconductor transistor is disclosed. The method includes the steps of: providing a semiconductor substrate; forming a gate structure on the semiconductor substrate; and performing a first ion implantation process to implant a first molecular cluster having carbon, boron, and hydrogen into the semiconductor substrate at two sides of the gate structure for forming a doped region, wherein the molecular weight of the first molecular cluster is greater than 100.

Abstract: A method for fabricating a metal-oxide semiconductor transistor is disclosed. First, a semiconductor substrate having a gate structure thereon is provided, and a spacer is formed around the gate structure. An ion implantation process is performed to implant a molecular cluster containing carbon, boron, and hydrogen into the semiconductor substrate at two sides of the spacer for forming a doped region. The molecular weight of the molecular cluster is preferably greater than 100. Thereafter, a millisecond annealing process is performed to activate the molecular cluster within the doped region.

Abstract: A method for forming a semiconductor structure includes providing a semiconductor substrate; forming a gate dielectric layer on the semiconductor substrate; forming a first silicon-containing layer on the gate dielectric layer, wherein the first silicon-containing layer is substantially free from p-type and n-type impurities; forming a second silicon-containing layer over the first silicon-containing layer, wherein the second silicon-containing layer comprises an impurity; and performing an annealing to diffuse the impurity in the second silicon-containing layer into the first silicon-containing layer.

Abstract: Method for simultaneously forming doped regions having different conductivity-determining type elements profiles are provided. In one exemplary embodiment, a method comprises the steps of diffusing first conductivity-determining type elements into a first region of a semiconductor material from a first dopant to form a doped first region. Second conductivity-determining type elements are simultaneously diffused into a second region of the semiconductor material from a second dopant to form a doped second region. The first conductivity-determining type elements are of the same conductivity-determining type as the second conductivity-determining type elements. The doped first region has a dopant profile that is different from a dopant profile of the doped second region.

Abstract: A method of manufacturing a semiconductor device comprises the steps of, in sequence: depositing a first silicon layer; patterning the first silicon layer to obtain a first silicon region; implanting a first dopant into a first part of the first silicon region, the first part of the first silicon region defined using a first mask; depositing a second silicon layer; patterning the second silicon layer to obtain a second silicon region; and implanting a second dopant into a second part of the first silicon region, the second part of the first silicon region defined by the first mask and the second silicon region. A device comprises a semiconductor layer (6); a first doped region (5) within the semiconductor layer; a second doped region (7) within the first doped region (5); and a silicon layer (9) disposed over a part of the semiconductor layer; wherein the silicon layer is disposed over a part of the first doped region (5) but not over the second doped region (7).

Abstract: A transistor includes; at least two polycrystalline silicon layers disposed substantially parallel to each other, each polycrystalline silicon layer including a channel region and at least two high conductivity regions disposed at opposing sides of the channel region; a gate which corresponds to the channel region of the two polycrystalline silicon layers and which crosses the two polycrystalline silicon layers, and a gate insulating layer interposed between the gate and the two polycrystalline silicon layers, wherein low conductivity regions are disposed adjacent to one edge of the gate and are formed between the channel region and one high conductivity region of each polycrystalline silicon 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: A photodiode in which a pn junction is formed between the doped region (DG) formed in the surface of a crystalline semiconductor substrate and a semiconductor layer (HS) deposited above said doped region. An additional doping (GD) is provided in the edge region of the doped zone, by means of which additional doping the pn junction is shifted deeper into the substrate (SU). With the greater distance of the pn junction from defects at phase boundaries that is achieved in this way, the dark current within the photodiode is reduced.

Abstract: In an atmosphere in which a silicon carbide (SiC) substrate implanted with impurities is annealed to activate the impurities, by setting a partial pressure of H2O to be not larger than 10?2 Pa, preferably not larger than 10?3 Pa, surface irregularity of the silicon carbide (SiC) substrate is controlled to be not greater than 2 nm, more preferably not greater than 1 nm in RMS value.

Abstract: A solar cell device and method of making are provided. The device includes a silicon substrate including a preexisting dopant. A homogeneous lightly doped region is formed on a surface of the silicon substrate to form a junction between the preexisting dopant and the lightly doped region. A heavily doped region is selectively implanted on the surface of the silicon substrate. A seed layer is formed over the heavily doped region. A metal contact is formed over the seed layer. The device can include an anti-reflective coating. In one embodiment, the heavily doped region forms a parabolic shape. The heavily doped regions can each be a width on the silicon substrate a distance in the range 50 to 200 microns. Also, the heavily doped regions can be laterally spaced on the silicon substrate a distance in the range 1 to 3 mm from each other. The seed layer can be a silicide.

Abstract: A method of forming a solar cell, the method comprising: providing a semiconducting wafer having a pre-doped region; performing a first ion implantation of a dopant into the semiconducting wafer to form a first doped region over the pre-doped region, wherein the first ion implantation has a concentration-versus-depth profile; and performing a second ion implantation of a dopant into the semiconducting wafer to form a second doped region over the pre-doped region, wherein the second ion implantation has a concentration-versus-depth profile different from that of the first ion implantation, wherein at least one of the first doped region and the second doped region is configured to generate electron-hole pairs upon receiving light, and wherein the first and second ion implantations are performed independently of one another.

Abstract: A semiconductor sensor device is formed using MEMS technology by placing a thin layer of single-crystal silicon, which includes semiconductor devices, over a cavity, which has been formed in a semiconductor material. The thin layer of single-crystal silicon can be formed by forming the semiconductor devices in the top surface of a single-crystal silicon wafer, thinning the silicon wafer to a desired thickness, and then dicing the thinned wafer to form silicon layers of a desired size. The MEMS device can be used to implement a pressure sensor, microphone, temperature sensor, and a joystick.

Abstract: A method of using a metal complex as an n-dopant for doping an organic semiconducting matrix material in order to alter the latter's electrical characteristics is provided. In order to provide n-doped organic semiconductors with matrix materials having a low reduction potential, while achieving high conductivities, the n-dopant is a neutral electron-rich metal complex with a neutral or charged transition metal atom as a central atom and having at least 16 valence electrons. The complex can be polynuclear and can possess at least one metal-metal bond. At least one ligand can form a ? complex with the central atom, which can be a bridge ligand, or it can contain at least one carbanion-carbon atom or a divalent atom. Methods for providing the novel n-dopants are provided.

Abstract: A semiconductor component and a method for manufacturing such a semiconductor component which has a resistance behavior which depends heavily on the temperature. This resistance behavior is obtained by a special multi-layer structure of the semiconductor component, one layer being designed in such a way that, for example, multiple p-doped regions are present in an n-doped region, said regions being short-circuited on one side via a metal-plated layer. For example, the semiconductor component may be used for reducing current peaks, by being integrated into a conductor. In the cold state, the semiconductor component has a high resistance which becomes significantly lower when the semiconductor component is heated as a result of the flowing current.

Abstract: There is provided a high power LED package and a method of manufacturing the same. The method includes: forming at least one chip mounting part and at least one through hole in a metal plate; forming an insulating layer of a predetermined thickness on an entire outer surface of the metal plate; forming an electrode part to be electrically connected to a light emitting chip mounted on the chip mounting part; and cutting the metal plate along a trimming line to separate the package. The LED package is free from thermal impact resulting from different thermal coefficients among components, thus ensuring stable heat radiation characteristics in a high temperature atmosphere. Also, the LED package is minimized in optical loss to improve optical characteristics. In addition, the LED package is simplified in a manufacturing and assembly process and thus can be manufactured in mass production at a lower cost.

Abstract: Provided is a method of fabricating a semiconductor probe with a resistive tip. The method includes steps of forming a mask layer on a substrate doped with first impurities and forming first and second semiconductor electrode regions heavily doped with the second impurities on the substrate uncovered by the mask layer, annealing the first and second semiconductor electrode regions and diffusing the second impurities of the first and second semiconductor electrode regions to portions facing each other to form resistive regions lightly doped with the second impurities at the outer boundaries of the first and second semiconductor electrode regions, and patterning the mask layer in a predetermined shape and etching a portion of a top surface of the substrate not covered by the patterned mask layer to form a resistive tip.

Abstract: A method for making a semiconductor device is described. That method includes forming on a substrate a dielectric layer that has a dielectric constant that is greater than the dielectric constant of silicon dioxide. The dielectric layer is modified so that it will be compatible with a gate electrode to be formed on the dielectric layer, and then a gate electrode is formed on the dielectric layer.