Abstract: Disclosed is a PNP ESD integrated circuit, including a substrate, an active region formed within the substrate, the active region including at least one base region of a second conductivity type, a plurality of collector regions of a first conductivity type formed within the active region, a plurality of emitter regions of the first conductivity type formed within the active region, and a local interconnect layer (LIL) contacting the plurality of emitter regions and the plurality of collector regions, the LIL including cooling fin contacts formed on the collector regions to enhance the current handling capacity of the collector regions.

Abstract: A solar cell including a base region, a back surface field layer and a delta doping layer positioned between the base region and the back surface field layer.

Abstract: The present invention discloses a bipolar transistor with an embedded epitaxial external base region, which is designed to solve the problem of the TED effect with the prior art structures. The bipolar transistor with an embedded epitaxial external base region of the present invention comprises at least a collector region, a base region and an external base region on the collector region, an emitter on the base region, and sidewalls at both sides of the emitter. The external base region is grown through an in-situ doping selective epitaxy process and is embedded in the collector region. A portion of the external base region is located beneath the sidewalls. The present invention discloses a method of forming a bipolar transistor with an embedded epitaxial external base region.

Abstract: A method for fabricating a photovoltaic device includes forming a patterned layer on a doped emitter portion of the photovoltaic device, the patterned layer including openings that expose areas of the doped emitter portion and growing an epitaxial layer over the patterned layer such that a crystalline phase grows in contact with the doped emitter portion and a non-crystalline phase grows in contact with the patterned layer. The non-crystalline phase is removed from the patterned layer. Conductive contacts are formed on the epitaxial layer in the openings to form a contact area for the photovoltaic device.

Abstract: A method for making an epitaxial structure is provided. The method includes the following steps. A substrate is provided. The substrate has an epitaxial growth surface for growing epitaxial layer. A first carbon nanotube layer is placed on the epitaxial growth surface. A first epitaxial layer is epitaxially grown on the epitaxial growth surface. A second carbon nanotube layer is placed on the first epitaxial layer. A second epitaxial layer is epitaxially grown on the first epitaxial layer.

Abstract: A semiconductor device and a method of fabricating the semiconductor device is provided. In the method, a semiconductor substrate defining a device region and an outer region at a periphery of the device region is provided, an align trench is formed in the outer region, a dummy trench is formed in the device region, an epi layer is formed over a top surface of the semiconductor substrate and within the dummy trench, a current path changing part is formed over the epi layer, and a gate electrode is formed over the current path changing part. When the epi layer is formed, a current path changing trench corresponding to the dummy trench is formed over the epi layer, and the current path changing part is formed within the current path changing trench.

Abstract: A method for depositing a silicon oxide layer on a substrate including a silicon region and a silicon-germanium region, including the steps of: forming a very thin silicon layer having a thickness ranging from 0.1 to 1 nm above silicon-germanium; and depositing a silicon oxide layer on the substrate.

Abstract: The present disclosure provides methods of semiconductor device fabrication for 3D devices. One method includes provide a substrate having a recess and forming a doping layer on the substrate and in the recess. The substrate is then annealed. The annealing drives dopants of a first type from the doping layer into the substrate. This can form a doped region that may be the source/drain extension of the 3D device. An epitaxial region is then grown in the recess. The epitaxial region can form the source/drain region of the 3D device.

Abstract: A method for making an epitaxial structure is provided. The method includes the following steps. A substrate is provided. The substrate has an epitaxial growth surface for growing epitaxial layer. A carbon nanotube layer is placed on the epitaxial growth surface. A plurality of epitaxial crystal grains spaced from each other is epitaxially grown on the epitaxial growth surface. Also, the carbon nanotube layer can be further removed.

Abstract: An annular step portion provided to a periphery of a wafer housing portion is provided to an area with which an area of 1 to 6 mm from a boundary line with a chamfered surface of a wafer rear surface toward a wafer center comes in contact. As a result, it is possible to produce an epitaxial wafer having no scratch in a boundary area between the rear surface and the chamfered surface, and to eliminate particles generated due to a scratch in a device process.

Abstract: In a semiconductor device according to the present invention, two epitaxial layers are formed on a P type substrate. In the substrate and the epitaxial layers, isolation regions are formed to divide the substrate and the epitaxial layers into a plurality of islands. Each of the isolation regions is formed by connecting first and second P type buried layers with a P type diffusion layer. By disposing the second P type buried layer between the first P type buried layer and the P type diffusion layer, a lateral diffusion width of the first P type buried layer is reduced. By use of this structure, a formation region of the isolation region is reduced in size.

Abstract: A transistor including a germanium-rich channel. The germanium-rich channel is produced by oxidation of the silicon contained in the silicon-germanium intermediate layer starting from the lower surface of the said intermediate layer. The germanium atoms are therefore caused to migrate towards the upper surface of the silicon-germanium intermediate layer, and are stopped by the gate insulating layer. The migration of the atoms during the oxidation step is thus less prejudicial to the performance of the transistor, since the gate insulator of the transistor has already been produced and is not modified during this step. The migration of the germanium atoms towards the gate insulator, which is immobile, leads to a limitation of the surface defects between the channel and the insulator.

Abstract: The illumination system has a light source (1) with a plurality of light emitters (R, G, B). The light emitters comprise at least a first light-emitting diode of a first primary color and at least a second light-emitting diode of a second primary color, the first and the second primary colors being distinct from each other. The illumination system has a facetted light-collimator (2) for collimating light emitted by the light emitters. The facetted lightcollimator is arranged along a longitudinal axis (25) of the illumination system. Light propagation in the facetted light-collimator is based on total internal reflection or on reflection at a reflective coating provided on the facets of the facetted light-collimator. The facetted light-collimator merges into a facetted light-reflector (3) at a side facing away from the light source. The illumination system further comprises a light-shaping diffuser (17). The illumination system emits light with a uniform spatial and spatio-angular color distribution.

Abstract: Methods of manufacturing semiconductor devices and structures thereof are disclosed. In one embodiment, a method of manufacturing a semiconductor device includes forming recesses in a first region and a second region of a workpiece. The first region of the workpiece is masked, and the recesses in the second region of the workpiece are filled with a first semiconductive material. The second region of the workpiece is masked, and the recesses in the first region of the workpiece are filled with a second semiconductive material.

Abstract: In a semiconductor device according to the present invention, two epitaxial layers are formed on a P type substrate. In the substrate and the epitaxial layers, isolation regions are formed to divide the substrate and the epitaxial layers into a plurality of islands. Each of the isolation regions is formed by connecting first and second P type buried layers with a P type diffusion layer. By disposing the second P type buried layer between the first P type buried layer and the P type diffusion layer, a lateral diffusion width of the first P type buried layer is reduced. By use of this structure, a formation region of the isolation region is reduced in size.

Abstract: A method of fabricating an integrated BiCMOS circuit is provided, the circuit including bipolar transistors 10 and CMOS transistors 12 on a substrate. The method comprises the step of forming an epitaxial layer 28 to form a channel region of a MOS transistor and a base region of a bipolar transistor. Growing of the epitaxial layer includes growing a first sublayer of silicon 28a, a first sublayer of silicon-germanium 28b onto the first sublayer of silicon, a second sublayer of silicon 28c onto the first sublayer of silicon-germanium, and a second sublayer of silicon-germanium 28d onto the second sublayer of silicon. Furthermore, an integrated BiCMOS circuit is provided, which includes an epitaxial layer 28 as described above.

Abstract: In a semiconductor device according to the present invention, two epitaxial layers are formed on a P type substrate. In the substrate and the epitaxial layers, isolation regions are formed to divide the substrate and the epitaxial layers into a plurality of islands. Each of the isolation regions is formed by connecting first and second P type buried layers with a P type diffusion layer. By disposing the second P type buried layer between the first P type buried layer and the P type diffusion layer, a lateral diffusion width of the first P type buried layer is reduced. By use of this structure, a formation region of the isolation region is reduced in size.

Abstract: Bipolar transistors and methods of forming the bipolar transistors. The method including forming a P-type collector in a silicon substrate; forming an intrinsic base on the collector, the intrinsic base including a first N-type dopant species, germanium and carbon; forming an N-type extrinsic base over a first region and a second region of the intrinsic base, the first region over the collector and the second region over a dielectric adjacent to the collector, the N-type extrinsic base containing or not containing carbon; and forming a P-type emitter on the first region of the intrinsic base.

Abstract: In a metal-oxide semiconductor (MOS) transistor with an elevated source/drain structure and in a method of fabricating the MOS transistor with the elevated source/drain structure using a selective epitaxy growth (SEG) process, a source/drain extension junction is formed after an epi-layer is formed, thereby preventing degradation of the source/drain junction region. In addition, the source/drain extension junction is partially overlapped by a lower portion of the gate layer, since two gate spacers are formed and two elevated source/drain layers are formed in accordance with the SEG process. This mitigates the short channel effect and reduces sheet resistance in the source/drain layers and the gate layer.

Abstract: An epitaxially grown channel layer is provided on a well structure after ion implantation steps and heat treatment steps are performed to establish a required dopant profile in the well structure. The channel layer may be undoped or slightly doped, as required, so that the finally obtained dopant concentration in the channel layer is significantly reduced compared to a conventional device to thereby provide a retrograde dopant profile in a channel region of a field effect transistor. Additionally, a barrier diffusion layer may be provided between the well structure and the channel layer to reduce up-diffusion during any heat treatments carried out after the formation of the channel layer. The final dopant profile in the channel region may be adjusted by the thickness of the channel layer, the thickness and the composition of the diffusion barrier layer and any additional implantation steps to introduce dopant atoms in the channel layer.

Abstract: A self-aligned bipolar transistor and a method of formation thereof are provided. The bipolar transistor has a raised extrinsic base such that the link base resistance is reduced by providing an extrinsic base which is thicker than the intrinsic base. The increase in thickness of the extrinsic base provides a less resistive layer of the heavily doped base region. The method of forming the bipolar transistor includes depositing a first epitaxial layer on a substrate to form a base region having an intrinsic base region and an extrinsic base region. The extrinsic base region is raised by depositing a second epitaxial layer over a portion of the first epitaxial layer such that the thickness of the extrinsic base layer is x and the thickness of the intrinsic layer is y, wherein x>y. The second epitaxial layer is deposited using a chemical vapor epitaxial device where the concentration of Ge to Si is gradually reduced from above 5% to close to 0% during the epitaxy process.

Abstract: One method includes epitaxially growing a layer of group III-nitride semiconductor under growth conditions that cause a growth surface to be rough. The method also includes performing an epitaxial growth of a second layer of group III-nitride semiconductor on the first layer under growth conditions that cause the growth surface to become smooth. The two-step growth produces a lower density of threading defects. Another method includes epitaxially growing a layer of group III-nitride semiconductor on a lattice-mismatched crystalline substrate and then, chemically treating a growth surface of the layer to selectively electrically passivate defects that thread the layer.

Abstract: The invention relates to a method of forming a trench filled with a thermally conducting material in a semiconductor substrate. In one embodiment, the method includes filling a portion of the trench with a thermally conducting material and patterning a contact to the thermally conducting material. The invention also relates to a semiconductor device. In one embodiment, the semiconductor device has a trench defining a cell region, wherein a portion of the trench includes a thermally conducting material, and a contact to the thermally conducting material. The invention further relates to a semiconductor device and a method of forming a semiconductor device with an interlayer dielectric that is a thermally conducting material.

Abstract: A method of forming a semiconductor device with an inductor and/or high speed interconnect. The method comprises forming an epitaxial layer over the substrate, forming an opening through the epitaxial layer to expose an underlying region of the substrate, forming a first dielectric material within the opening of the epitaxial layer, planarizing the first dielectric layer, forming a second dielectric material layer over the first dielectric material layer, and then forming a metallized inductor over the second dielectric material layer above the opening of the epitaxial layer. In this case, since the inductor and the high speed interconnect do not overlie the conductive epitaxial layer, the degradation in the Q-factor of the inductor, loss characteristics of the high speed interconnect, and ‘cross-talk’ between conductors are substantially reduced. The resulting semiconductor device is also disclosed.

Abstract: A semiconductor device fabrication method includes the steps of forming a first insulation layer and a first semiconductor layer sequentially on a semiconductor substrate having a buried diffusion region therein. A second insulation layer is formed on the first semiconductor layer. The first insulation layer, the first semiconductor layer, and the second insulation layer are then patterned to create openings that expose the buried diffusion region. A third insulation layer is formed on respective side walls of the openings on the exposed portions of the first semiconductor layer, first insulation layer and second insulation layer that form the openings. A first epitaxial layer is formed on the semiconductor substrate exposed through the openings. A second epitaxial layer is then formed on the first epitaxial layer to be connected to the first semiconductor layer, thereby forming an active base region and a second conductive type collector region in the second epitaxial layer of the first and second openings.

Abstract: A method of forming a semiconductor device with an inductor and/or high speed interconnect. The method comprises forming an epitaxial layer over the substrate, forming an opening through the epitaxial layer to expose an underlying region of the substrate, forming a first dielectric material within the opening of the epitaxial layer, planarizing the first dielectric layer, forming a second dielectric material layer over the first dielectric material layer, and then forming a metallized inductor over the second dielectric material layer above the opening of the epitaxial layer. In this case, since the inductor and the high speed interconnect do not overlie the conductive epitaxial layer, the degradation in the Q-factor of the inductor, loss characteristics of the high speed interconnect, and ‘cross-talk’ between conductors are substantially reduced. The resulting semiconductor device is also disclosed.

Abstract: A semiconductor structure and method of processing same including a substrate, a lattice-mismatched first layer deposited on the substrate and annealed at a temperature greater than 100° C. above the deposition temperature, and a second layer deposited on the first layer with a greater lattice mismatch to the substrate than the first semiconductor layer. In another embodiment there is provided a semiconductor graded composition layer structure on a semiconductor substrate and a method of processing same including a semiconductor substrate, a first semiconductor layer having a series of lattice-mismatched semiconductor layers deposited on the substrate and annealed at a temperature greater than 100° C. above the deposition temperature, a second semiconductor layer deposited on the first semiconductor layer with a greater lattice mismatch to the substrate than the first semiconductor layer, and annealed at a temperature greater than 100° C.

Abstract: According to a disclosed embodiment, the surface of a semiconductor wafer is covered by an etch stop layer. For example, the etch stop layer can be composed of silicon dioxide. A cap layer is then fabricated over the etch stop layer. For example, the cap layer can be a polycrystalline silicon layer fabricated over the etch stop layer. The cap layer is then selectively etched down to the etch stop layer creating an opening in the cap layer according to a pattern. The pattern can be formed, for example, by covering the cap layer with photoresist and selective etching. Selective etching can be accomplished by using a dry etch process which etches the cap layer without substantially etching the etch stop layer. The etch stop layer is then removed using, for example, a hydrogen-fluoride cleaning process. A semiconductor crystal is then grown by epitaxial deposition in the opening. For example, the semiconductor crystal can be silicon-germanium. Moreover, a single crystal semiconductor structure of high quality, i.

Abstract: A number of npn and pnp bipolar transistors are formed in a single chip of silicon, so that some of the transistors have a greater frequency response than others The higher frequency transistors have their emitters located closer to the collectors, by positioning a collector, or emitter, of a transistor in a recessed portion of the surface of the chip. The recess is formed in an accurate and controlled manner by locally oxidising the silicon surface, and subsequently removing the oxide to leave the recess.

Abstract: A manufacturing process is carried out starting from an SOI type wafer including a top silicon layer and a bottom silicon layer separated from each other by a buried silicon dioxide layer. In the top layer, a LOCOS type sacrificial region is formed and then removed, so as to form a cavity that extends in depth as far as the buried oxide layer. Subsequently, the cavity is filled with epitaxial or polycrystalline silicon, so as to form a power region extending between the top surface and the bottom surface of the wafer; then lateral insulation regions are formed that insulate the power region from the circuitry region.

Abstract: A vertically-isolated bipolar transistor occupying reduced surface area is fabricated by circumscribing an expected active device region within a first narrow trench. The first trench is filled with sacrificial material impermeable to diffusion of conductivity-altering dopant, and then isolation dopant of a conductivity type opposite to that of the substrate is introduced into the trench-circumscribed silicon region. The introduced isolation dopant is then thermally driven into the substrate, with lateral diffusion of isolation dopant physically constrained by the existing first narrow trench. Epitaxial silicon is then formed over the substrate, with polysilicon formed in regions overlying the filled narrow trench. A second, wider trench encompassing the first trench is etched to consume epitaxial silicon, polysilicon, and the sacrificial material. The second trench is then filled with dielectric material.

Abstract: A transistor including an epitaxial layer with a first conductivity type, a base buried region with a second conductivity type, and a sinker base region with the second conductivity type which extends from a main surface of the transistor to the base buried region, and delimits, together with the base buried region, emitter fingers in the epitaxial layer. The transistor further includes an emitter buried region with the first conductivity type and a doping level which is higher than that of the epitaxial layer. The emitter buried region is embedded in the epitaxial layer in a position adjacent to the base buried region. A sinker emitter region having the first conductivity type and a doping level which is higher than that of the epitaxial layer and extends from the main surface to the emitter buried region inside the emitter fingers.

Abstract: A method for fabricating a buried layer pinched collector bipolar, (BPCB), device, sharing several process steps with simultaneously formed CMOS devices, has been developed. The BPCB device fabrication sequence features the use of polysilicon field plates,. placed on field oxide regions, in an area of an N well region in which the field oxide regions are located between subsequent P type, base and N type, collector regions. The use of the polysilicon field plates results in an increase in collector—emitter breakdown voltage, as a result of a reduction in the electric field at the surface underlying the polysilicon field plates.

Abstract: Base layer formation without the use of selective epitaxial deposition is described. The process begins with the deposition of a seed layer of polysilicon over both the field oxide and the wafer surface that lies between them. An opening in said seed layer is then formed, between the areas of field oxide (and overlying an N+ buried layer). Non-selective epitaxial growth is then used to deposit the transistor's base layer. This automatically results in the formation of self aligned butted contacts of polysilicon on either side of the base. Manufacture of the transistor is completed in the usual way—emitter formation, emitter poly contact formation, ILD deposition, etc.

Abstract: A method of manufacturing a BICMOS integrated circuit including an NPN transistor in a heavily-doped P-type wafer coated with a lightly-doped P-type layer, including the steps of forming an N well of collector of a bipolar transistor; coating the structure with a polysilicon seed layer and opening above collector well portions; growing undoped silicon, then P-type doped silicon to form a single-crystal silicon base region; depositing an insulating layer and opening it; depositing N-type emitter polysilicon and etching it outside useful areas; etching the base silicon outside useful areas; forming spacers; and forming a collector contact area at the same time as the drain implantation of the N-channel MOS transistors.

Abstract: A method of fabricating a high power bipolar junction transistor. A P-type substrate having an N-type buried region is provided and a trench is formed within the substrate to expose the buried region. N-type ions are implanted and driven into the sidewall of the trench to form a sinker. Since the area and the depth of implantation are larger and deeper than that in prior art, the concentration of the sinker is more uniform and the diffusion range is easily controlled. An N-type epitaxial layer is then formed in the trench and an emitter, a base and their contacts are formed by conventional technique.

Abstract: A semiconductor device and method of fabrication for such device in which a P- epitaxial layer is positioned above a P++ substrate. A P++ buried layer implant is positioned within the device between the P++ substrate and the P- epitaxial layer. A connecting p+ implant is placed within the epitaxial layer above the buried p+ blanket layer implant. In one exemplary embodiment, the device includes a shallow P-well with the P+ connecting implant in a position within the epitaxial layer connecting the shallow P-well and the buried P+ blanket implant layer.

Abstract: An improved method and an apparatus for forming a self-aligned epitaxial base bipolar transistor in a semiconductor material is disclosed. The method of the invention involves forming an intrinsic base region formed by growing an epitaxial semiconductor material over a collector region. A raised sacrificial emitter core is then formed on the intrinsic base region followed by depositing a substantially conformal spacer layer over the sacrificial emitter core. Next, the spacer material is anisotropically etched such that a protective spacer ring is formed about the sacrificial emitter core. An extrinsic base is then formed by implanting dopant into the epitaxial base region wherein the sacrificial emitter core and the spacer ring preserve an emitter region. The spacer ring also serves to self-align the extrinsic base region to the emitter region. The protective sacrificial emitter core and spacer ring are then removed.

Abstract: A method of producing a semiconductor device having a bipolar transistor and a CMOS (Complementary Metal Oxide Semiconductor) transistor is disclosed. An epitaxial layer is formed on a semiconductor substrate having an n-type buried layer and a p-type buried layer thereinside. A field oxide film is formed on the epitaxial layer for delimiting active regions. An n-type and a p-type well region each is formed in a particular position. An insulation film playing the role of a gate oxide film at the same time is formed over the entire surface of the substrate. Subsequently, an emitter contact hole and a collector contact hole each extending to the epitaxial layer are formed at the same time. A polysilicon layer is formed over the entire surface of the substrate and then etched to form an emitter electrode and a gate electrode each having a preselected configuration. The resulting semiconductor device achieves a desirable current drive ability.

Abstract: A heteroepitaxial semiconductor device having reduced density of threading dislocations and a process for forming such a device. According to one embodiment, the device includes a substrate which is heat treated to a temperature in excess of 1000.degree. C., a film of arsenic formed on the substrate at a temperature between 800.degree. C. and 840.degree. C., a GaAs nucleation layer of less than 200 angstroms and formed at a temperature between about 350.degree. C. and 450.degree. C., and a plurality of stacked groups of layers of InP, wherein adjacent InP layers are formed at different temperatures.

Abstract: A manufacturing method of the present invention comprises the first step of forming an epitaxial base layer in an opening of an element-isolating oxide film on a semiconductor substrate in a non-selection condition, the second step of growing a silicon oxide film on the epitaxial base layer and a base polysilicon layer, and the third step of etching the silicon oxide film to expose the polysilicon layer by the etch-back or the CMP. According to this method, the silicon oxide film is left only on the epitaxial base layer, and the planarization of the device can be attained. The present invention also reduces the resistance of the base electrode by providing silicide to the device.

Abstract: To enable a high speed operation and to increase the current gain, the disclosed a method of manufacturing a semiconductor device, comprising the steps of: forming a first semiconductor layer with a first-conductivity type in a semiconductor substrate; forming a second semiconductor layer with a second-conductivity type different from the first-conductivity type on the first semiconductor layer; insulation separating the formed second semiconductor layer into a first semiconductor region and a second semiconductor region by an insulating film; changing the second semiconductor region to the first-conductivity type; forming a pattern of an insulating film or a photoresist film having a hole at a partial area of the first semiconductor region of the semiconductor substrate; and implanting first-conductivity type impurities and second-conductivity type impurities at the first semiconductor region, respectively by use of the formed pattern as a mask, to form a first-conductivity type impurity region contacting wi