Abstract: A new single optical interband transition occurs at the corresponding p-doping state of the carbon nanotubes in the VIS-NIR region when the degree of p-doping of carbon nanotubes is increased beyond a certain degree. P-doped carbon nanotubes to exhibit the new single optical interband transition in the VIS-NIR region may be used for devices so as to improve sensitivity and selectivity of the devices.

Abstract: A method of manufacturing a semiconductor device having a polycrystalline silicon layer (5) includes; a step of forming a mask layer (7) on the polycrystalline silicon layer (5); a step of forming a side wall (8) that is provided on a side face of the mask layer (7) and covers part of the polycrystalline silicon layer (6); a step of doping an impurity (52) into the polycrystalline silicon layer (5) by using at least one of the mask layer (7) and the side wall (8) as a mask; and a step of etching the polycrystalline silicon layer (5, 6) by using at least one of the mask layer (7) and the side wall (8) as a mask.

Abstract: A stressed film applied across a boundary defined by a structure or a body (e.g. substrate or layer) of semiconductor material provides a change from tensile to compressive stress in the semiconductor material proximate to the boundary and is used to modify boron diffusion rate during annealing and thus modify final boron concentrations. In the case of a field effect transistor, the gate structure may be formed with or without sidewalls to regulate the location of the boundary relative to source/drain, extension and/or halo implants. Different boron diffusion rates can be produced in the lateral and vertical directions and diffusion rates comparable to arsenic can be achieved. Reduction of junction capacitance of both nFETs and pFETs can be achieved simultaneously with the same process steps.

Abstract: A method of fabricating a diode is disclosed. One embodiment provides a semiconductor body having a front and a back, opposite the front in a vertical direction of the semiconductor body. The semiconductor body contains, successively in the vertical direction from the back to the front, a heavily n-doped zone, a weakly n-doped zone, a weakly p-doped zone and a heavily p-doped zone. In the vertical direction, the weakly p-doped zone has a thickness of at least 25% and at most 50% of the thickness of the semiconductor body.

Abstract: A method and device for reducing a dopant diffusion rate in a doped semiconductor region is provided. The methods and devices include selecting a plurality of dopant elements. Selection of a plurality of dopant elements includes selecting a first dopant element with a first atomic radius larger than a host matrix atomic radius and selecting a second dopant element with a second atomic radius smaller than a host matrix atomic radius. The methods and devices further include selecting amounts of each dopant element of the plurality of dopant elements wherein amounts and atomic radii of each of the plurality of dopant elements complement each other to reduce a host matrix lattice strain. The methods and devices further include introducing the plurality of dopant elements to a selected region of the host matrix and annealing the selected region of the host matrix.

Abstract: The invention provides a method for forming a deep well region of a power device, including: providing a substrate with a first sacrificial layer thereon; forming a first patterned mask layer on the first sacrificial layer exposing a first open region; performing a first doping process to the first open region to form a first sub-doped region; removing the first patterned mask layer and the first sacrificial layer; forming an epitaxial layer on the substrate; forming a second sacrificial layer on the epitaxial layer; forming a second patterned mask layer on the second sacrificial layer exposing a second open region; performing a second doping process to the second open region to form a second sub-doped region; removing the second patterned mask layer; performing an annealing process to make the first and the second sub-doped regions form a deep well region; and removing the second sacrificial layer.

Abstract: The present invention generally relates to nanotechnology and sub-microelectronic circuitry, as well as associated methods and devices, for example, nanoscale wire devices and methods for use in determining nucleic acids or other analytes suspected to be present in a sample (for example, their presence and/or dynamical information), e.g., at the single molecule level. For example, a nanoscale wire device can be used in some cases to detect single base mismatches within a nucleic acid (e.g., by determining association and/or dissociation rates). In one aspect, dynamical information such as a binding constant, an association rate, and/or a dissociation rate, can be determined between a nucleic acid or other analyte, and a binding partner immobilized relative to a nanoscale wire. In some cases, the nanoscale wire includes a first portion comprising a metal-semiconductor compound, and a second portion that does not include a metal-semiconductor compound.

Abstract: Methods of making Si-containing films that contain relatively high levels of Group III or Group V dopants involve chemical vapor deposition using trisilane and a dopant precursor. Extremely high levels of substitutional incorporation may be obtained, including crystalline silicon films that contain at least about 3×1020 atoms cm?3 of an electrically active dopant. Substitutionally doped Si-containing films may be selectively deposited onto the crystalline surfaces of mixed substrates by introducing an etchant gas during deposition.

Abstract: An impurity region having a box-shaped impurity profile is formed. An impurity introducing method includes a step of introducing a desired impurity into a surface of a solid base body, and a step of radiating plasma to a surface of the solid base body after the impurity introducing step thus forming an impurity profile having an approximately box-shape.

Abstract: A one-step diffusion method for fabricating a differential doped solar cell is described. The one-step diffusion method includes the following step. First, a substrate is provided. A doping control layer is formed on the substrate. The doping control layer includes a plurality of openings therein.

Abstract: Some embodiments include methods in which microwave radiation is used to activate dopant and/or increase crystallinity of semiconductor material during formation of a semiconductor construction. In some embodiments, the microwave radiation has a frequency of about 5.8 gigahertz, and a temperature of the semiconductor construction does not exceed about 500° C. during the exposure to the microwave radiation.

Abstract: A semiconductor integrated circuit is reduced in size by suppressing lateral extension of an impurity region when impurities in the impurity region are thermally diffused in a semiconductor substrate. A second photoresist is formed on an insulation film. The second photoresist is formed to have second openings K2 on both sides of a P-type impurity region so that the second openings K2 partially overlap the P-type impurity region. The insulation film is etched off together with an underlying surface of the semiconductor substrate using the second photoresist as a mask so as to remove the P-type impurity region partially. Then, phosphorus ions (P+) are implanted into the surface of the semiconductor substrate in the etched-off regions using the second photoresist as a mask to form N-type impurity regions that are adjacent the P-type impurity region. After removing the second photoresist, the impurities in the P-type impurity region and the impurities in the N-type impurity region are thermally diffused.

Abstract: Compositions are provided, comprising a host and a dopant, wherein the weight:weight ratio of host:dopant is about 10:1 to about 40:1, and a solvent, and methods for making the same, as well as devices and sub-assemblies including the same.

Abstract: Phosphorous-comprising dopants, methods for forming phosphorous-doped regions in a semiconductor material, and methods for fabricating phosphorous-comprising dopants are provided. In one embodiment, a phosphorous-comprising dopant comprises a phosphorous source comprising a phosphorous-comprising salt, a phosphorous-comprising acid, phosphorous-comprising anions, or a combination thereof, an alkaline material, cations from an alkaline material, or a combination thereof, and a liquid medium.

Abstract: Methods for uniformly optically annealing regions of a semiconductor substrate and methods for fabricating semiconductor substrates using uniform optical annealing are provided. In accordance with an exemplary embodiment, a method for uniformly optically annealing a semiconductor substrate comprises the step of obtaining an optical reflectance of a first region of the semiconductor substrate. A second region of the semiconductor substrate is fabricated such that the optical reflectance of the second region is substantially equal to the optical reflectance of the first region, wherein the first region is not the second region. The semiconductor substrate is optically annealed.

Abstract: A method for manufacturing a semiconductor device has the steps of: (a) implanting boron (B) ions into a semiconductor substrate; (b) implanting fluorine (F) or nitrogen (N) ions into the semiconductor device; (c) after the steps (a) and (b) are performed, executing first annealing with a heating time of 100 msec or shorter relative to a region of the semiconductor substrate into which ions were implanted; and (d) after the step (c) is performed, executing second annealing with a heating time longer than the heating time of the first annealing, relative to the region of the semiconductor substrate into which ions were implanted. The method for manufacturing a semiconductor device is provided which can dope boron (B) shallowly and at a high concentration.

Abstract: A laterally diffused metal oxide semiconductor (LDMOS) device and a method of manufacture therefor. The method of manufacturing the LDMOS device includes forming an amorphous region in a semiconductor substrate between isolation structures and adjacent a gate structure, by implanting an amorphizing element, such as silicon or germanium, in the semiconductor substrate. The method further includes diffusing a channel dopant laterally in the amorphous region, to form a first portion of a channel.

Abstract: Dopant diffusion into semiconductor material is controlled during fabrication of a semiconductor structure by depositing a nucleation layer over a first layer of the semiconductor structure and depositing a device layer containing the dopant over the nucleation layer. The nucleation layer serves as a diffusion barrier by limiting in depth the diffusion of the dopant into the first layer. The dopant can include arsenic (As).

Abstract: A method of manufacturing silicon nano wires including forming microgrooves on a surface of a silicon substrate, forming a first doping layer doped with a first dopant on the silicon substrate and forming a second doping layer doped with a second dopant between the first doping layer and a surface of the silicon substrate, forming a metal layer on the silicon substrate, forming catalysts by heating the metal layer within the microgrooves of the silicon substrate and growing the nano wires between the catalysts and the silicon substrate using a thermal process.

Abstract: An ON resistance of a trench gate type transistor and a withstand voltage of a planar type transistor are optimized at the same time. Each of first and second regions of a semiconductor layer is formed by epitaxial growth on each of first and second regions of a semiconductor substrate, respectively. A first buried layer is formed between the first region of the semiconductor substrate and the first region of the semiconductor layer, while a second buried layer is formed between the second region of the semiconductor substrate and the second region of the semiconductor layer. The first buried layer is formed of an N+ type first impurity-doped layer and an N type second impurity-doped layer that extends beyond the fist impurity-doped layer. The second buried layer is formed of an N+ type impurity-doped layer only. In the first region of the semiconductor layer, an impurity is diffused from a surface of the semiconductor layer deep into the semiconductor layer to form an N type third impurity-doped layer.

Abstract: A method of forming a multi-doped junction on a substrate is disclosed. The method includes providing the substrate doped with boron, the substrate including a first substrate surface with a first surface region and a second surface region. The method also includes depositing a first set of nanoparticles on the first surface region, the first set of nanoparticles including a first dopant. The method further includes heating the substrate in an inert ambient to a first temperature and for a first time period creating a first densified film, and further creating a first diffused region with a first diffusion depth in the substrate beneath the first surface region.

Abstract: A thermal oxidation method capable of obtaining a high oxidation rate by generating a sufficient enhanced-rate oxidation phenomenon even in a low temperature region is provided. In addition, a thermal oxidation method capable of forming a silicon oxide film having a high reliability even when formed at a low temperature region. A basic concept herein is to form a silicon oxide film by thermal reaction by generating a large amount of oxygen radicals (O*) having a large reactivity without using plasma. More specifically, ozone (O3) and other active gas are reacted, so that ozone (O3) is decomposed highly efficiently even in a low temperature region, thereby generating a large amount of oxygen radicals (O*). For example, a compound gas containing a halogen element can be used as the active gas.

Abstract: This invention discloses a process of phosphorus diffusion for manufacturing solar cell, comprising annealing a mono-crystalline silicon wafer in a nitrogen atmosphere at 900-950° C. for twenty to thirty minutes, carrying oxidation treatment in a hydrogen chloride atmosphere at 850-1050° C. to form a 10 to 30 nm thick oxide layer on the surface of said silicon wafer, diffusing from a phosphorus source at 850-900° C., until a block resistance of a material surface is controlled at 40 to 50 ohms, and the junction depth is at 0.2 to 1.0 microns, and annealing in a nitrogen atmosphere at 700-750° C. for thirty to sixty minutes to complete the phosphorus diffusion of said mono-crystalline silicon wafer. This invention allows the use of 4 N˜5 N mono-crystalline silicon as the material for manufacturing solar cells, so, the low purity material such as metallurgical silicon can be used, which greatly reduces the cost of materials.

Abstract: In a physical vapor transport method and system, a growth chamber charged with source material and a seed crystal in spaced relation is provided. At least one capsule having at least one capillary extending between an interior thereof and an exterior thereof, wherein the interior of the capsule is charged with a dopant, is also provided. Each capsule is installed in the growth chamber. Through a growth reaction carried out in the growth chamber following installation of each capsule therein, a crystal is formed on the seed crystal using the source material, wherein the formed crystal is doped with the dopant.

Abstract: A method of manufacture for semiconductor electronic products and a circuit structure. A semiconductor material has a surface region and dopant is provided to a portion of the surface region. The portion of the surface region provided with the dopant is irradiated with sufficient energy to induce diffusion of the dopant from the portion of the surface region to another region of the semiconductor material. A method for manufacturing an electronic product with a semiconductor material having a surface and two spaced-apart regions along the surface for receiving dopant includes forming a field effect transistor gate structure is along the surface and over a third region of the surface between the two spaced-apart regions. Dopant is provided to the spaced-apart regions which are heated to a temperature at least 50 degrees C. higher than the peak temperature which results in the third region when the spaced-apart regions are heated.

Abstract: A method for forming a diffused, doped backside layer on a device wafer oxide bonded to a handle wafer in an integrated circuit is provided. The method comprises forming a thermal bond oxide layer on a backside surface of the device wafer of the integrated circuit. Implanting the bond oxide with a diffusing dopant. Diffusing dopant from the bond oxide into the backside surface of the device wafer. Depositing an oxide layer on the bond oxide and bonding the deposited oxide layer to the handle wafer of the integrated circuit.

Abstract: Provided are a method of doping a carbon nanotube (CNT) of a field effect transistor and a method of controlling the position of doping ions. The method may include providing a source, a drain, the CNT as a channel between the source and the drain, and a gate, applying a first voltage to the gate, and adsorbing ions on a surface of the CNT.

Abstract: A well region in which an insulated gate semiconductor element is formed is a diffusion region, and an impurity concentration of the well region is lower toward its bottom portion. This leads to a problem of increased resistance. Therefore, particularly, an insulated gate semiconductor element having an up-drain structure has a problem of increased on-resistance. A p type well region is formed by stacking two p type impurity regions on one another. The p type impurity regions are allowed to serve as the p type well region by sequentially stacking n type semiconductor layers, on one another, having p type impurities implanted into their surfaces and simultaneously diffusing the impurities by heat treatment. In this way, it is possible to obtain the p type well region in which an impurity concentration sufficient to secure a desired breakdown voltage is maintained approximately uniform up to a desired depth.

Abstract: A method of manufacturing a semiconductor device having a polycrystalline silicon layer (5) includes; a step of forming a mask layer (7) on the polycrystalline silicon layer (5); a step of forming a side wall (8) that is provided on a side face of the mask layer (7) and covers part of the polycrystalline silicon layer (6); a step of doping an impurity (52) into the polycrystalline silicon layer (5) by using at least one of the mask layer (7) and the side wall (8) as a mask; and a step of etching the polycrystalline silicon layer (5, 6) by using at least one of the mask layer (7) and the side wall (8) as a mask.

Abstract: A method for manufacturing a semiconductor device includes forming a diffusion layer on a silicon substrate by doping an impurity of a first conductivity type into a region of a second conductivity type opposite to the first conductivity type and performing a heat treatment; implanting nitrogen or fluorine ions into the diffusion layer; and irradiating carbon dioxide gas laser light to the diffusion layer after the implanting.

Abstract: The aim of the invention is to improve the energy yield efficiency of solar cells. According to the invention, the silicon material is doped with one or more different lanthanides such that said material penetrates into a layer approximately 60 nm deep. Photons, whose energy is at least double that of the 1.2 eV silicon material band gap, are thus converted into at least two photons having energy in the region of the silicon band gap, by excitation and recombination of the unpaired 4f electrons of the lanthanides. As a result, additional photons having advantageous energy close to the silicon band gap are provided for electron-hole pair formation.

Abstract: A semiconductor light emitting device includes an active region, an n-type region, and a p-type region comprising a portion that extends into the active region. The active region may include multiple quantum wells separated by barrier layers, and the p-type extension penetrates at least one of the quantum well layers. The extensions of the p-type region into the active region may provide uniform filling of carriers in the individual quantum wells of the active region by providing direct current paths into individual quantum wells. Such uniform filling may improve the operating efficiency at high current density by reducing the carrier density in the quantum wells closest to the bulk p-type region, thereby reducing the number of carriers lost to nonradiative recombination.

Abstract: Semiconductor component or device is provided which includes a current barrier element and for which the impedance may be tuned (i.e. modified, changed, etc.) using a focused heating source.

Abstract: A semiconductor device comprises a memory cell region, a peripheral circuit region and a boundary region. In the memory cell region, a concave lower electrode and a foundation layer have a same uppermost surface positioned in a height of H above the plane-A. In the boundary region, one concave lower conductive region and a foundation layer have a same uppermost surface positioned in a height of H above the plane-A.

Abstract: A semiconductor fabrication method. The method includes providing a semiconductor structure which includes (i) a semiconductor layer, (ii) a gate dielectric layer on the semiconductor layer, and (iii) a gate electrode region on the gate dielectric layer. The gate dielectric layer is sandwiched between and electrically insulates the semiconductor layer and the gate electrode region. The semiconductor layer and the gate dielectric layer share a common interfacing surface which defines a reference direction perpendicular to the common interfacing surface and pointing from the semiconductor layer to the gate dielectric layer. Next, a resist layer is formed on the gate dielectric layer and the gate electrode region. Next, a cap portion of the resist layer directly above the gate electrode region in the reference direction is removed without removing any portion of the resist layer not directly above the gate electrode region in the reference direction.

Abstract: A semiconductor device according to one embodiment includes: a semiconductor substrate; a first impurity diffusion suppression layer formed on the semiconductor substrate for suppressing diffusion of a channel impurity; an impurity channel layer formed on the first impurity diffusion suppression layer and containing the channel impurity; a second impurity diffusion suppression layer formed on the impurity channel layer for suppressing diffusion of the channel impurity; a channel layer formed on the second impurity diffusion suppression layer; a gate insulating film formed on the channel layer; and a gate electrode formed on the gate insulating film.

Abstract: A semiconductor device and a method for manufacturing the same are disclosed. The disclosed semiconductor device includes a semiconductor substrate having a device isolation structure for delimiting an active region, the active region being recessed and grooves being defined in channel forming areas of the active region; gates formed in and over the grooves; gate spacers formed on both sidewalls of the gates over portions of the recessed active region which are positioned on both sides of the gates; an LDD region formed in the active region under the gate spacers; junction areas formed in the active region on both sides of the gates including the gate spacers; and landing plugs formed on the junction areas.

Abstract: A method to create piezoresistive sensing elements and electrostatic actuator elements on trench sidewalls is disclosed. P-type doped regions are formed in the upper surface of an n-type substrate. A trench is formed in the substrate (e.g. by DRIE process) intersecting with the doped regions and defining a portion of the substrate which is movable in the plane of the substrate relative to the rest of the substrate. Then diffusion of P-type dopant into the trench side-walls creates piezoresistive elements and electrode elements for electrostatic actuation. Owing to the intersection of two doped regions, there are good electrical paths between the electrical elements on the trench side-walls and the previously P-type doped portions on the wafer surface. The trench intersects with insulating elements, so that insulating elements mutually insulate adjacent electrical elements. P-n junctions between the electrical elements and the substrate insulate the electrical elements from the substrate.

Abstract: A system and method is disclosed for providing a deep connection to a substrate or buried layer of a semiconductor device. Three shallow trenches are etched halfway through a layer of epitaxial silicon that is located on a substrate. A second doped layer is created in the epitaxial silicon layer at the bottom of the central shallow trench. First and third doped layers are created in the epitaxial silicon layer adjacent to the central shallow trench. An oxide layer is then deposited to fill the three trenches. The second doped layer is diffused vertically down to the substrate. The first and third doped layers are diffused vertically down to the second doped layer. Lateral diffusion of the first and third doped layers is constrained by the oxide layer in the three trenches.

Abstract: A masking paste used as a mask for controlling diffusion when diffusing a p-type dopant and an n-type dopant into a semiconductor substrate and forming a high-concentration p-doped region and a high concentration n-doped region is provided that contains at least a solvent, a thickening agent, and SiO2 precursor and/or a TiO2 precursor, Further, a manufacturing method of a solar cell is provided in which the masking paste is pattern-formed on the semiconductor substrate and then the p-type dopant and the n-type dopant are diffused.

Abstract: A method for the structuring of multicrystalline silicon substrate surfaces and emitter diffusion into said surfaces comprises the following steps: providing a texturing solution which comprises at least a portion of phosphoric acid, providing a semiconductor substrate with a surface to be structured, coating the surface to be structured with the texturing solution, heating the texturing solution to a heating temperature TT, and heating the texturing solution to a diffusion temperature TD, wherein TD>TT.

Abstract: Semiconductor doping techniques, along with related methods and structures, are disclosed that produce components having a more tightly controlled source and drain extension region dopant profiles without significantly inducing gate edge diode leakage. The technique follows the discovery that carbon, which may be used as a diffusion suppressant for dopants such as boron, may produce a gate edge diode leakage if present in significant quantities in the source and drain extension regions. As an alternative to placing carbon in the source and drain extension regions, carbon may be placed in the source and drain regions, and the thermal anneal used to activate the dopant may be relied upon to diffuse a small concentration of the carbon into the source and drain extension regions, thereby suppressing dopant diffusion in these regions without significantly inducing gate edge diode leakage.

Abstract: A method of manufacturing a non-volatile memory device is provided. The method includes forming isolation patterns defining an active region on a substrate, forming a floating gate pattern on the active region, and forming a gate line on the floating gate pattern. The floating gate pattern is self-aligned on the active region and has an impurity ion concentration that becomes relatively low as the floating gate pattern gets nearer to the active region.

Abstract: Method and device for doping or diffusion, or oxidation of silicon wafers (4), the wafers being introduced into the chamber (2) of an oven (1) wherein is introduced at least a gas for performing the doping or diffusion or oxidation process. The method comprises simultaneously with the introduction and passage of gas into the chamber (2) of the oven (1), continuously subjecting the latter to a depression of constant value. The device comprises an oven (1) provided with a chamber (2) wherein are introduced the wafers, the oven including at least an inlet tube (5a, 5b, 5c) for introducing at least a gas into the chamber (2) to carry out the processes and at least an outlet tube (6) for extracting the gas whereto is connected a suction unit (7) for generating in the chamber (2) a constant and controlled depression.

Abstract: Systems and methods for lithography include actuating an electroactive polymer member to position mask and/or substrate.

Abstract: A transistor which includes halo regions disposed in a substrate adjacent to opposing sides of the gate. The halo regions have upper and lower regions. The upper region is a crystalline region with excess vacancies and the lower region is an amorphous region. Source/drain diffusion regions are disposed in the halo regions. The source/drain diffusion regions overlap the upper and lower halo regions. This architecture offers the minimal extension resistance as well as minimum lateral diffusion for better CMOS device scaling.

Abstract: ?-Hydroxy carboxylic acid etchants for silicon microstructures are generally described. In one example, a method includes fabricating a protruding structure on a semiconductor substrate, the protruding structure comprising a first layer of silicon coupled with the semiconductor substrate, the first layer of silicon defining a bottom gate, a sacrificial layer of silicon germanium (SiGe) coupled with the first layer of silicon, and a second layer of silicon coupled with the layer of SiGe, fabricating a top gate that traverses the protruding structure, and selectively etching the sacrificial layer of SiGe using an etchant including hydrofluoric acid (HF), nitric acid (HNO3), and an ?-hydroxy carboxylic acid to enable doping of at least the first layer of silicon prior to selectively etching the sacrificial layer of SiGe.

Abstract: A semiconductor wafer for semiconductor components and to a method for its production is disclosed. In one embodiment, the semiconductor wafer includes a front side with an adjoining near-surface active zone as basic material for semiconductor component structures. The rear side of the semiconductor wafer is adjoined by a getter zone for gettering impurity atoms in the semiconductor wafer. The getter zone contains oxygen precipitates. In the near-surface active zone, atoms of doping material are located on lattice vacancies. The atoms of doping material have a higher diffusion coefficient that the oxygen atoms.

Abstract: Memory devices having improved TPD characteristics and methods of making the memory devices are provided. The memory devices contain two or more memory cells on a semiconductor substrate and bit line dielectrics between the memory cells. The bit line dielectrics can extend into the semiconductor. The memory cell contains one or more charge storage nodes, a first poly gate, a pair of first bit lines, and a pair of second bit lines. The second bit line can be formed at a higher energy level, a higher concentration of dopants, or a combination thereof compared to an energy level and a concentration of dopants of the first bit line.

Abstract: A P-type polysilicon layer having a stable and desired resistivity is formed by alternately depositing a plurality of silicon atom layers and a plurality of group IIIA element atom layers on a semiconductor substrate by atomic layer deposition, and thereafter forming a P-type polysilicon layer by thermally diffusing the plurality of group IIIA element atom layers into the plurality of silicon atom layers. The plurality of group IIIA element atom layers may comprise Al, Ga, In, and/or Tl.