Abstract: Methods for doping a three-dimensional semiconductor structure are disclosed. A conformal coating is formed on the three-dimensional semiconductor structure by Atomic Layer Deposition, and subsequent annealing causes dopant atoms to migrate into the three-dimensional semiconductor structure. Any residual conformal coating is then removed by etching. The semiconductor can be a type IV semiconductor such as Si, SiC, SiGe, or Ge, for which Sb and Te are suitable dopants. Sb and Te can be provided from a Ge2Sb2Te5 conformal coating. The semiconductor can also be a type III-V semiconductor such as InGaAs, GaAs, InAs, or GaSb, for which Sn and S are suitable dopants. Sn and S can be provided from a SnS conformal coating. The dopant concentration can be adjusted by precise control over the number of monolayers deposited in a conformal coating layer deposited by ALD.

Abstract: After adding phosphorus (P) and germanium (Ge) into a silicon melt or adding phosphorus into a silicon/germanium melt, a silicon monocrystal is grown from the silicon melt by a Czochralski method, where a phosphorus concentration [P]L(atoms/cm3) in the silicon melt, a Ge concentration in the silicon monocrystal, an average temperature gradient Gave (K/mm) and a pull speed V (mm/min) are controlled to satisfy a formula (1) as follows, a phosphorus concentration [P](atoms/cm3) and the Ge concentration [Ge](atoms/cm3) in the silicon monocrystal satisfy a relationship according to a formula (2) as follows while growing the silicon monocrystal, where dSi(?) represents a lattice constant of silicon, rSi(?) represents a covalent radius of silicon, rP(?) represents a covalent radius of phosphorus, and rGe(?) represents a covalent radius of Ge: [ P ] L + ( 0.3151 × [ Ge ] + 3.806 × 10 18 ) / 1.5 < 0.

Abstract: A method of processing a substrate having horizontal and non-horizontal surfaces is disclosed. The substrate is implanted with particles using an ion implanter. During the ion implant, due to the nature of the implant process, a film may be deposited on the surfaces, wherein the thickness of this film is thicker on the horizontal surfaces. The presences of this film may adversely alter the properties of the substrate. To rectify this, a second process step is performed to remove the film deposited on the horizontal surfaces. In some embodiments, an etching process is used to remove this film. In some embodiments, a material modifying step is used to change the composition of the material comprising the film. This material modifying step may be instead of, or in addition to the etching process.

Abstract: After adding phosphorus (P) and germanium (Ge) into a silicon melt or adding phosphorus into a silicon/germanium melt, a silicon monocrystal is grown from the silicon melt by a Czochralski method, where a phosphorus concentration [P]L (atoms/cm3) in the silicon melt, a Ge concentration in the silicon monocrystal, an average temperature gradient Gave (K/mm) and a pull speed V (mm/min) are controlled to satisfy a formula (1) as follows, the phosphorus concentration [P] (atoms/cm3) in the silicon monocrystal is 4.84×1019 atoms/cm3 or more and 8.49×1019 atoms/cm3 or less, and the phosphorus concentration [P] (atoms/cm3) and the Ge concentration [Ge] (atoms/cm3) in the silicon monocrystal satisfy a relationship according to a formula (2) as follows while growing the silicon monocrystal. [P]L+(0.3151×[Ge]+3.806×1019)/1.5<0.5×(Gave/V+43)×1019??(1) [Ge]?6.95×[P]+5.90×1020??(2).

Abstract: A method of tailoring the dopant profile of a substrate by utilizing two different dopants, each having a different diffusivity is disclosed. The substrate may be, for example, a solar cell. By introducing two different dopants, such as by ion implantation, furnace diffusion, or paste, it is possible to create the desired dopant profile. In addition, the dopants may be introduced simultaneously, partially simultaneously, or sequentially. Dopant pairs preferably consist of one lighter species and one heavier species, where the lighter species has a greater diffusivity. For example, dopant pairs such as boron and gallium, boron and indium, phosphorus and arsenic, and phosphorus and antimony, can be utilized.

Abstract: The present invention relates to a semiconductor device which is capable of simultaneously improving a short channel effect of a PMOS and the current of an NMOS and a method for manufacturing the same. The semiconductor device includes first and second gates formed over first and second areas of a semiconductor substrate, respectively; and first and second junction areas formed in a portion of the semiconductor substrate corresponding to both sides of the first gate and a portion of the semiconductor substrate corresponding to both sides of the second gate, and including a projection, respectively, wherein the projection of the first junction area has a height higher than the height of the projection of the second junction area, and the second junction area is formed such that it has a depth from the surface of the semiconductor substrate deeper than the depth of the first junction area.

Abstract: A method for forming a selective emitter of a solar cell and a diffusion apparatus for forming the same are provided. The method includes texturing a surface of a silicon substrate by etching the silicon substrate, coating an impurity solution on the surface of the silicon substrate, injecting a first thermal energy into the whole surface of the silicon substrate, and, while the first thermal energy is injected into the whole surface of the silicon substrate, injecting a second thermal energy by irradiating a laser beam into a partial region of the surface of the silicon substrate.

Abstract: A manufacturing method of a NOR flash memory with phosphorous and arsenic ion implantations mainly implants both phosphorous and arsenic ions on a drain area of a transistor memory unit, and controls specific energy and dosage for the implantation to reduce the defects of a memory device and improve the yield rate of the NOR flash memory.

Abstract: A semiconductor device has a semiconductor substrate of a first conductivity type; first to third high-voltage insulated-gate field effect transistors formed on a principal surface of the semiconductor substrate; a first device isolation insulating film that is formed in the semiconductor substrate and isolates the first high-voltage insulated-gate field effect transistor and the second high-voltage insulated-gate field effect transistor from each other; a second device isolation insulating film that is formed in the semiconductor substrate and isolates the first high-voltage insulated-gate field effect transistor and the third high-voltage insulated-gate field effect transistor from each other; a first impurity diffusion layer of the first conductivity type that is formed below the first device isolation insulating film; and a second impurity diffusion layer of the first conductivity type that is formed below the second device isolation insulating film.

Abstract: Embodiments of the invention generally provide methods for end point detection at predetermined dopant concentrations during plasma doping processes. In one embodiment, a method includes positioning a substrate within a process chamber, generating a plasma above the substrate and transmitting a light generated by the plasma through the substrate, wherein the light enters the topside and exits the backside of the substrate, and receiving the light by a sensor positioned below the substrate. The method further provides generating a signal proportional to the light received by the sensor, implanting the substrate with a dopant during a doping process, generating multiple light signals proportional to a decreasing amount of the light received by the sensor during the doping process, generating an end point signal proportional to the light received by the sensor once the substrate has a final dopant concentration, and ceasing the doping process.

Abstract: Performance of field effect transistors and other channel dependent devices formed on a monocrystalline substrate is improved by carrying out a high temperature anneal in a nitrogen releasing atmosphere while the substrate is coated by a sacrificial oxide coating containing easily diffusible atoms that can form negatively charged ions and can diffuse deep into the substrate. In one embodiment, the easily diffusible atoms comprise at least 5% by atomic concentration of chlorine atoms in the sacrificial oxide coating and the nitrogen releasing atmosphere includes NO. The high temperature anneal is carried out for less than 10 hours at a temperature less than 1100° C.

Abstract: Embodiments of the invention generally provide methods for end point detection at predetermined dopant concentrations during plasma doping processes. In one embodiment, a method includes positioning a substrate within a process chamber, generating a plasma above the substrate and transmitting a light generated by the plasma through the substrate, wherein the light enters the topside and exits the backside of the substrate, and receiving the light by a sensor positioned below the substrate. The method further provides generating a signal proportional to the light received by the sensor, implanting the substrate with a dopant during a doping process, generating multiple light signals proportional to a decreasing amount of the light received by the sensor during the doping process, generating an end point signal proportional to the light received by the sensor once the substrate has a final dopant concentration, and ceasing the doping process.

Abstract: In a trench-gated MOSFET including an epitaxial layer over a substrate of like conductivity and trenches containing thick bottom oxide, sidewall gate oxide, and conductive gates, body regions of the complementary conductivity are shallower than the gates, and clamp regions are deeper and more heavily doped than the body regions but shallower than the trenches. Zener junctions clamp a drain-source voltage lower than the FPI breakdown of body junctions near the trenches, but the zener junctions, being shallower than the trenches, avoid undue degradation of the maximum drain-source voltage. The epitaxial layer may have a dopant concentration that increases step-wise or continuously with depth. Chained implants of the body and clamp regions permits accurate control of dopant concentrations and of junction depth and position. Alternative fabrication processes permit implantation of the body and clamp regions before gate bus formation or through the gate bus after gate bus formation.

Abstract: A semiconductor device has a substrate and a dielectric film formed directly or indirectly on the substrate. The dielectric film contains a metal silicate film, and a silicon concentration in the metal silicate film is lower in a center portion in the film thickness direction than in an upper portion and in a lower portion.

Abstract: A MOS transistor and subsurface collectors can be formed by using a hard mask and precisely varying the implant angle, rotation, dose, and energy. In this case, a particular atomic species can be placed volumetrically in a required location under the hard mask. The dopant can be implanted to form sub-silicon volumes of arbitrary shapes, such as pipes, volumes, hemispheres, and interconnects.

Abstract: A method of selecting plasma doping process parameters includes determining a recipe parameter database for achieving at least one plasma doping condition. The initial recipe parameters are determined from the recipe parameter database. In-situ measurements of at least one plasma doping condition are performed. The in-situ measurements of the at least one plasma doping condition are correlated to at least one plasma doping result. At least one recipe parameter is changed in response to the correlation so as to improve at least one plasma doping process performance metric.

Abstract: A semiconductor circuit with a depletion-mode transistor is formed with a method that eliminates the need for a separate mask and implant step to set the threshold voltage of the depletion-mode transistor. As a result, the method of the present invention reduces the cost and complexity associated with the fabrication of a semiconductor circuit that includes a depletion-mode transistor.

Abstract: The invention provides a method for manufacturing a semiconductor device with which an impurity introduction region and a positioning mark region can be formed aligned, based on a common insulating film pattern.

Abstract: A surface mount connector assembly for mounting to a printed wiring board (PWB) in a low-profile manner. The height of the surface mount connector assembly is diminished because the connector assembly extends from one side of the PWB to the other through an opening in the PWB. The surface mount connector assembly includes an outer housing portion having a plurality of openings therethrough for receiving a plurality of electrical contacts. The surface mount connector also includes an inner housing portion to be nested within the outer housing portion. Each of the electrical contacts are configured to be received within one of the openings in the inner housing portion such that a portion of each contact extends into the interior of the inner housing portion and another portion of each contact extends to the exterior of the inner housing portion.

Abstract: A method of forming a retrograde well in a transistor is provided. A transistor structure having a substrate, a gate, and a gate oxide layer between the substrate and the gate is formed. The substrate includes a channel region located generally below the gate. A first dopant is implanted into the channel region. A second dopant is implanted into the substrate to form a doped source region and a doped drain region. A third dopant is implanted into the gate oxide layer. A source/drain anneal is performed to form a source and a drain in the doped source region and the doped drain region, respectively. The source/drain anneal causes a portion of the first dopant in the channel region to be attracted by the third dopant into the gate oxide layer.

Abstract: The present invention describes a method of manufacturing a semiconductor device, comprising a semiconductor substrate in the shape of a slice, the method comprising the steps of: step 1) selectively applying a pattern of a solids-based dopant source to a first major surface of said semiconducting substrate; step 2) diffusing the dopant atoms from said solids-based dopant source into said substrate by a controlled heat treatment step in a gaseous environment surrounding said semi-conducting substrate, the dopant from said solids-based dopant source diffusing directly into said substrate to form a first diffusion region and, at the same time, diffusing said dopant from said solids-based dopant source indirectly via said gaseous environment into said substrate to form a second diffusion region in at least some areas of said substrate to form a second diffusion region in at least some areas of said substrate not covered by said pattern; and step 3) forming a metal contact pattern substantially in alignment with

Abstract: A double diffused field effect transistor and a method of forming the same is provided. The method begins by providing a substrate of a first conductivity type. Next, at least one dopant species, also of the first conductivity type, is introduced into a surface of the substrate so that the substrate has a nonuniform doping profile. An epitaxial layer of the first conductivity type is formed over the substrate and one or more body regions of a second conductivity type are formed within the epitaxial layer. A plurality of source regions of the first conductivity type are then formed within the body regions. Finally, a gate region is formed, which is adjacent to the body regions.

Abstract: An integrated circuit and a method of fabricating the same are disclosed. Complementary bipolar transistors (20p, 20n) are fabricated as vertical bipolar transistors. The emitter polysilicon (35), which is in contact with the underlying single-crystal base material, is doped with a dopant for the appropriate device conductivity type, and also with a diffusion retardant, such as elemental carbon, SiGeC, nitrogen, and the like. The diffusion retardant prevents the dopant from diffusing too fast from the emitter polysilicon (35). Device matching and balance is facilitated, especially for complementary technologies.

Abstract: A thin film photovoltaic devices is described, having a glass substrate 11 over which is formed a thin film silicon device having an n++ layer 12, a p layer 13 and a dielectric layer 14 (typically silicon oxide or silicon nitride). To create a connection through the p layer 13 to the underlying n++ layer 12, a column of semi-conductor material is heated, the column passing through the various doped layers and the material in the column being heated or melted to allow migration of dopant between layer of the device in the region of the column.

Abstract: The invention relates to a power MOSFET and reduction of the number of mask steps in a process of fabricating the power MOSFET. The increase of a parasitic capacitance due to the reduction is suppressed. In place of a thick insulating film 3, a gate insulating film 12 is formed on the entire surface of a semiconductor substrate. The gate-drain parasitic capacitance which uses the gate insulating film as a dielectric is suppressed by forming a removal region EL.

Abstract: A method of forming a memory device from a single transistor and a single RTD structure is provided. The method comprises the steps of forming a silicon base, an oxide layer over the base and a top thin silicon layer over the oxide layer. The top silicon layer has a first region and a second region. The second region is masked and a transistor device is formed in the first region of the top silicon layer. Next, the first region is masked and a vertical RTD device is formed in the second region. The step of forming a vertical RTD device in the second region comprises implanting a n+ dopant to form concurrently a source and drain region of the transistor device and a generally horizontal N+ quantum well region of the vertical RTD device. The drain region of the transistor device is coupled to the quantum well region of the vertical RTD. The N+ quantum well region is disposed horizontally below a top surface of the second region.

Abstract: A method is disclosed in which a lightly doped region in a semiconductor layer is obtained by diffusing dopant atoms of a first and second type into the underlying semiconductor layer. Preferably, the method is applied to the formation of lightly doped source and drain regions in a field effect transistor so as to obtain a required gradual dopant concentration transition from the general region to the drain and source regions for avoiding the hot carrier effect. Advantageously, a diffusion of the dopant atoms is initiated during an oxidizing step in which the thickness of the gate insulation layer is increased at the edge portions thereof.

Abstract: A transistor of a second conductivity type is of an LMOS structure, and a transistor of a first conductivity type is of an LDMOS structure. The transistor of the first conductivity type has a drain base layer which functions in the same manner as a drain offset diffusion layer and is formed in a substrate separately from a source base diffusion layer. The transistor of the first conductivity type has a stably high breakdown voltage and a low on-state resistance as with the transistor of the second conductivity type.

Abstract: An impurity concentration profile that improves pn junction breakdown voltage and mitigates the electric field, and that does not adversely affect the characteristics of a field effect transistor is realized. An n type source/drain region is formed at a silicon substrate. A p type impurity concentration profile. includes respective peak concentrations at a dope region for forming a p type well, a p type channel cut region, and a p type channel dope region. An impurity concentration profile of the n type source/drain region crosses the p type impurity concentration profile at a low concentration, and includes phosphorus implantation regions indicating impurity concentrations respectively higher than those of the p type channel cut region and the p type channel dope region and respective peaks in impurity concentration at the neighborhood of respective depth thereof.

Abstract: Power semiconductor devices having recessed gate electrodes are formed by methods which include the steps of forming a semiconductor substrate having a drift region of first conductivity type therein extending to a face thereof and forming a trench in the substrate so that the trench has a bottom which extends opposite the drift region and a sidewall which extends from the drift region to the face. The sidewall may extend orthogonal to the face or at an angle greater than 90°. A preferred insulated gate electrode is formed by lining the face and trench with a gate electrode insulating layer and then forming a conductive layer on the gate electrode insulating layer. The conductive layer is preferably formed to extend opposite a portion of the face adjacent to the trench and into the trench. A step is then performed to pattern the conductive layer to define a T-shaped or Y-shaped gate electrode which fills the trench and also extends opposite the face at a location adjacent the trench.

Abstract: The present invention discloses a semiconductor device having a PNP bipolar transistor and an NPN bipolar transistor having excellent transistor characteristics formed on the same semiconductor substrate, and a method of manufacturing the semiconductor device. This semiconductor device is provided with a first n-type well and a second n-type well formed at substantially the same depths in a semiconductor substrate, an NPN bipolar transistor formed within the first n-type well which uses the n-type well as its collector, a p-type well formed within the second n-type well, and a PNP bipolar transistor formed within the p-type well which uses the p-type well as its collector.

Abstract: A method and structure providing a dual layer silicon gate film having a uniform boron distribution therein and an ordered, uniform grain structure. Rapid thermal annealing is used to cause the diffusion of boron from an originally doped film to an originally undoped film, resulting in a uniform boron distribution within the structure, thereby rendering the structure resistant to vertical and lateral diffusion of the boron during subsequent processing at elevated temperatures.

Abstract: A process for forming a modified polysilicon plug structure, used to connect a bit line structure, of a semiconductor memory device, to an underlying source and drain region, of a transfer gate transistor, has been developed. The process features the formation of a dual shaped opening in an insulator layer, comprised of a wide, upper opening, overlying a narrower, lower opening, which exposes the top surface of a source and drain region. Polysilicon deposition and patterning result in the formation of the modified polysilicon plug structure, comprised of a wide polysilicon trench shape, in the upper opening in the insulator layer, and an underlying, narrower polysilicon plug, in the lower opening, in the insulator layer, with the narrow polysilicon plug contacting the underlying source and drain region. An overlying bit line structure is formed, contacting the top surface of the underlying, polysilicon trench shape, exposed in a bit line via hole.

Abstract: A method for making n-type semiconducting diamond by use of CVD in which n-type impurities are doped simultaneously with the deposition of diamond. As the n-type impurities, an Li compound and a B compound, both, are used at once. After doping, a diamond film thus obtained is etched to peel off its surface. The n-type semiconducting diamond is superior in specific resistivity, 10.sup.-2 .OMEGA.cm or less.

Abstract: A method of fabricating a MOS-gated semiconductor device in which arsenic dopant is implanted through a mask to form a first layer, boron dopant is implanted through the mask to form a second layer deeper than the first layer, and in which a single diffusion step diffuses the implanted arsenic and the implanted boron at the same time to form a P+ body region with an N+ source region therein and a P type channel region.