Abstract: A bipolar transistor includes a collector layer, a base layer, and an emitter layer that are formed in this order on a compound semiconductor substrate. The emitter layer is disposed inside an edge of the base layer in plan view. A base electrode is disposed on partial regions of the emitter layer and the base layer so as to extend from an inside of the emitter layer to an outside of the base layer in plan view. An insulating film is disposed between the base electrode and a portion of the base layer, with the portion not overlapping the emitter layer. An alloy layer extends from the base electrode through the emitter layer in a thickness direction and reaches the base layer. The alloy layer contains at least one element constituting the base electrode and elements constituting the emitter layer and the base layer.

Abstract: A method for forming a semiconductor device includes forming a metal gate stack having a gate dielectric layer and a gate electrode disposed over the gate dielectric layer. The gate electrode includes a first metal layer and a second metal layer. The method further includes performing a plasma treatment to a top surface of the metal gate stack and forming a conductive layer over the treated top surface of the metal gate stack. A top portion of the conductive layer is formed above a top surface of the gate dielectric layer, and a bottom portion of the conductive layer penetrates into the first and the second metal layers of the gate electrode at different distances.

Abstract: Conductivity improvements in III-V semiconductor devices are described. A first improvement includes a barrier layer that is not coextensively planar with a channel layer. A second improvement includes an anneal of a metal/Si, Ge or SiliconGermanium/III-V stack to form a metal-Silicon, metal-Germanium or metal-SiliconGermanium layer over a Si and/or Germanium doped III-V layer. Then, removing the metal layer and forming a source/drain electrode on the metal-Silicon, metal-Germanium or metal-SiliconGermanium layer. A third improvement includes forming a layer of a Group IV and/or Group VI element over a III-V channel layer, and, annealing to dope the III-V channel layer with Group IV and/or Group VI species. A fourth improvement includes a passivation and/or dipole layer formed over an access region of a III-V device.

Abstract: A method that forms a structure implants a well implant into a substrate, patterns a mask on the substrate (to have at least one opening that exposes a channel region of the substrate) and forms a conformal dielectric layer on the mask and to line the opening. The conformal dielectric layer covers the channel region of the substrate. The method also forms a conformal gate metal layer on the conformal dielectric layer, implants a compensating implant through the conformal gate metal layer and the conformal dielectric layer into the channel region of the substrate, and forms a gate conductor on the conformal gate metal layer. Additionally, the method removes the mask to leave a gate stack on the substrate, forms sidewall spacers on the gate stack, and then forms source/drain regions in the substrate partially below the sidewall spacers.

Abstract: A photovoltaic cell is provided as a composite unit together with elements of an integrated circuit on a common substrate. In a described embodiment, connections are established between a multiple photovoltaic cell portion and a circuitry portion of an integrated structure to enable self-powering of the circuitry portion by the multiple photovoltaic cell portion.

Abstract: Threshold voltage controlled semiconductor structures are provided in which a conformal nitride-containing liner is located on at least exposed sidewalls of a patterned gate dielectric material having a dielectric constant of greater than silicon oxide. The conformal nitride-containing liner is a thin layer that is formed using a low temperature (less than 500° C.) nitridation process.

Abstract: A method of forming a SOI substrate, diodes in the SOI substrate and electronic devices in the SOI substrate and an electronic device formed using the SOI substrate. The method of forming the SOI substrate includes forming an oxide layer on a silicon first substrate; ion-implanting hydrogen through the oxide layer into the first substrate, to form a fracture zone in the substrate; forming a doped dielectric bonding layer on a silicon second substrate; bonding a top surface of the bonding layer to a top surface of the oxide layer; thinning the first substrate by thermal cleaving of the first substrate along the fracture zone to form a silicon layer on the oxide layer to formed a bonded substrate; and heating the bonded substrate to drive dopant from the bonding layer into the second substrate to form a doped layer in the second substrate adjacent to the bonding layer.

Abstract: Methods are disclosed for forming a varied impurity profile for a collector using scattered ions while simultaneously forming a subcollector. In one embodiment, the invention includes: providing a substrate; forming a mask layer on the substrate including a first opening having a first dimension; and substantially simultaneously forming through the first opening a first impurity region at a first depth in the substrate (subcollector) and a second impurity region at a second depth different than the first depth in the substrate. The breakdown voltage of a device can be controlled by the size of the first dimension, i.e., the distance of first opening to an active region of the device. Numerous different sized openings can be used to provide devices with different breakdown voltages using a single mask and single implant. A semiconductor device is also disclosed.

Abstract: A method of forming a SOI substrate, diodes in the SOI substrate and electronic devices in the SOI substrate and an electronic device formed using the SOI substrate. The method of forming the SOI substrate includes forming an oxide layer on a silicon first substrate; ion-implanting hydrogen through the oxide layer into the first substrate, to form a fracture zone in the substrate; forming a doped dielectric bonding layer on a silicon second substrate; bonding a top surface of the bonding layer to a top surface of the oxide layer; thinning the first substrate by thermal cleaving of the first substrate along the fracture zone to form a silicon layer on the oxide layer to formed a bonded substrate; and heating the bonded substrate to drive dopant from the bonding layer into the second substrate to form a doped layer in the second substrate adjacent to the bonding layer.

Abstract: By providing a novel bipolar device design implementation, a standard CMOS process (105-109) can be used unchanged to fabricate useful bipolar transistors (80) and other bipolar devices having adjustable properties by partially blocking the P or N well doping (25) used for the transistor base (581). This provides a hump-shaped base (583, 584) region with an adjustable base width (79), thereby achieving, for example, higher gain than can be obtained with the unmodified CMOS process (101-104) alone. By further partially blocking the source/drain doping step (107) used to form the emitter (74) of the bipolar transistor (80), the emitter shape and effective base width (79) can be further varied to provide additional control over the bipolar device (80) properties. The embodiments thus include prescribed modifications to the masks (57, 62, 72, 46) associated with the bipolar device (80) that are configured to obtain desired device properties.

Abstract: A method for producing an integrated circuit including a trench transistor and an integrated circuit is disclosed.

Abstract: There is provided a semiconductor device including a semiconductor substrate (10), a high concentration diffusion region (22) formed within the semiconductor substrate (10), a first low concentration diffusion region (24) that has a lower impurity concentration than the high concentration diffusion region (22) and is provided under the high concentration diffusion region (22), and a bit line (30) that includes the high concentration diffusion region (22) and the first low concentration diffusion region (24) and serves as a source region and a drain region, and a manufacturing method therefor. Reduction of source-drain breakdown voltage of the transistor is suppressed, and a low-resistance bit line can be formed. Thus, a semiconductor device that can miniaturize memory cells and a manufacturing method therefor can be provided.

Abstract: A method for manufacturing a semiconductor optical device includes forming a BDR (Band Discontinuity Reduction) layer of a first conductivity type doped with an impurity, depositing a contact layer of the first conductivity type in contact with the BDR layer after forming the the BDR layer, the contact layer being doped with the same impurity as the BDR layer and used to form an electrode, and heat treating after forming the contact layer.

Abstract: Disclosed is a method of forming a transistor in an integrated circuit structure that begins by forming a collector in a substrate and an intrinsic base above the collector. Then, the invention patterns an emitter pedestal for the lower portion of the emitter on the substrate above the intrinsic base. Before actually forming the emitter or associates spacer, the invention forms an extrinsic base in regions of the substrate not protected by the emitter pedestal. After this, the invention removes the emitter pedestal and eventually forms the emitter where the emitter pedestal was positioned.

Abstract: A CMOS image sensor and a method of fabricating the same are provided. The CMOS image sensor includes: a semiconductor substrate of a first conductivity type having a photodiode region and a transistor region defined therein; a gate electrode formed above the transistor region of the semiconductor substrate with a gate insulating layer interposed therebetween; a first impurity region formed of the first conductivity type in the semiconductor substrate below the gate electrode and having a higher concentration of first conductivity type ions than the semiconductor substrate; and a second impurity region formed of a second conductivity type in the photodiode region of the semiconductor substrate.

Abstract: A boron ion stream may be used to implant ions, such as boron ions, into the sidewalls of an active area, such as an NFET active area. The boron ion stream has both vertical tilt and horizontal rotation components relative to the sidewalls and/or the silicon device, to provide a better line of sight onto the sidewalls. This may allow components of the silicon device to be moved closer together without unduly reducing the effectiveness of boron doping of NFET active area sidewalls, and provides an improved line of sight of a boron ion stream onto the sidewalls of an NFET active area prior to filling the surrounding trench with STI material.

Abstract: A semiconductor device suitable for applications in an electrostatic discharge (ESD) protection circuit, including a semiconductor substrate, a first well formed in the substrate, a second well formed in the substrate, and a first doped region formed in the second well, wherein the first well, the second well, and the first doped region collectively form a parasitic bipolar junction transistor (BJT), and wherein the first well is the collector of the BJT, the second well is the base of the BJT, and the first doped region is the emitter of the BJT.

Abstract: A diffusion barrier (and method for forming the diffusion barrier) for a field-effect transistor having a channel region and a gate electrode, includes an insulating material being disposed over the channel region. The insulating material includes nitrogen (N), and is disposed under the gate electrode. The insulating material can be provided either as a layer or distributed within a gate dielectric material disposed under the gate electrode.

Abstract: A method for forming a lateral SCR device for on-chip ESD protection in shallow-trench-isolation CMOS process is provided. In the present lateral SCR device, the shallow trench isolation among the current conduction path of the lateral SCR device is removed and instead of a dummy gate. Thereby, the SCR device has a narrower anode-to-cathode spacing, and then the lateral SCR device can be turned on more quickly to protect the CMOS IC's in ESD events. Additionally, the silicon area of the substrate occupied by the lateral SCR device is also saved. This method for forming a lateral SCR device without shallow-trench-isolation regions in its current path can be fully process-compatible to general CMOS technologies by only changing layout patterns in the mask layers.

Abstract: During the production of integrated semiconductor structures, it is often necessary to differently dope immediately adjacent regions. A method is provided for producing two adjacent regions of a predetermined area in an integrated semiconductor, whereby a first region of the two adjacent regions includes a doping with a lower target concentration than a second region. The predetermined area of a semiconductor blank is doped with a dopant until a concentration of the dopant is obtained that is at least as high as the target concentration of the second region. A protective layer is applied to the second region, and the dopant is out-diffused from the first region until a concentration of dopant is obtained that corresponds to the target concentration of the first region.

Abstract: A heterojunction bipolar transistor is doped in the sub-collector layer (20) with phosphorus (24). The presence of the phosphorus causes any interstitial gallium (22) to be bonded (26) to the phosphorus (24) and move to a lattice site. The result is that the interstitial gallium does not diffuse to the base layer and thus does not cause the beryllium to be displaced and diffused. Instead of doping with phosphorus, a layer including phosphorus can also be utilized.

Abstract: A semiconductor device is disclosed, including: a semiconductor substrate; a gate electrode formed on the semiconductor substrate; a first gate insulating layer formed between the gate electrode and semiconductor substrate, and formed at a first region including one edge of the gate electrode; a second gate insulating layer formed between the gate electrode and semiconductor substrate, and formed at a second portion including the other edge of the gate electrode, the second gate insulating layer being thicker than the first gate insulating layer; a first impurity region formed in a predetermined portion of the semiconductor substrate, placed on both sides of the gate electrode; and a second impurity region formed in a predetermined portion of the semiconductor substrate, placed under the second gate insulating layer.

Abstract: In a method for forming an array of dynamic random access memory (DRAM) cells, each DRAM cell having one or more field effect transistors (FETs) and a deep trench capacitor, first, a substrate is prepared. Line type active areas (AAs) are patterned on the substrate to thereby provide AA lines (AALs). Next, deep trench capacitors (DTCs) are fabricated in an AAL in a predetermined configuration to thereby define deep trench areas (DTAs) for the DTCs, each DTC having a storage node, a collar insulator and a buried strap. In subsequent step, a node isolation area (NIA) is defined to isolate a storage node of a DTC and a storage node of its adjacent DTC and then a trench isolation area (TIA) for each of the DRAM cell is defined. Further, one or more FETs are fabricated in each AA to thereby form the array of DRAM cells, wherein a conductive path is formed from an electrode of one of the FETs to the buried strap of a corresponding DTC.

Abstract: A method of decapsulating a packaged die includes removing packaging material from the bottom section of a die-containing package to expose a die pan, removing the die pan, removing material between the die pan and the bottom surface of the die, using the bottom surface of the die to determine a grind plane substantially parallel to the top surface of the die, and removing packaging material from the top section of the die-containing package to form a top surface substantially planar to the grind plane, preferably intersecting the wire bonds on the face of the die.

Abstract: A process for fabricating a bipolar junction transistor, featuring the use of multiple self-aligned collector regions, used to limit the width of the base region of the transistor, has been developed. The self-aligned collector regions are formed via multiple ion implantation procedures, performed through, and self-aligned to, an overlying emitter opening, in an oxide layer. The self-aligned collector regions, completely fill the space in the lighter doped collector region, located between the overlying base region, and the underlying subcollector region.

Abstract: A bi-MOS circuit is fabricated on first active regions assigned to the bipolar transistor and on second active regions assigned to the field effect transistors, and the field effect transistors are fabricated after said bipolar transistor, because a high-temperature heat treatment for an emitter diffusion destroys the impurity profiles of the source/drain regions of the field effect transistors, wherein a part of the field oxide layer between the second active regions is covered with an etching stopper layer before deposition of a thick silicon oxide layer in order to widely space the emitter region from the emitter electrode, even though the thick silicon oxide layer is removed from the field oxide layer between the second active regions for fabricating the field effect transistors, the etching stopper layer prevents the field oxide layer from the etchant, and the field oxide layer between the second active regions maintains the original thickness, thereby never allowing a parasitic MOS transistor to turn on

Abstract: Methods of forming bipolar junction transistors include the steps of forming a semiconductor substrate having a highly doped buried collector region therein and an intrinsic collector region extending from the buried collector region to a face of the semiconductor substrate. A first electrically insulating layer and first polysilicon layer are formed on the face. Separate masking and ion implantation steps are then performed to convert the first polysilicon layer into a highly doped first portion of first conductivity type and a highly doped second portion of second conductivity type. The first conductive layer may be patterned to define the emitter contact and base contact and expose the intrinsic collector region.

Abstract: A silicon on insulator (SOI) process is disclosed which includes the steps of forming an etch stop layer in a starting wafer, forming an insulating layer on the etch stop layer, bonding this wafer to a handle wafer, thinning the start wafer down to the etch stop and then recovering a device layer from the etch stop layer by outgassing dopants from the etch stop layer.

Abstract: In a method of manufacturing a semiconductor device, an insulating film is formed on a surface of a p-type semiconductor region, and then removed from a selected portion of the p-type semiconductor region. An n-type region having a high concentration of arsenic atoms is formed in a surface layer of the selected portion of the p-type semiconductor region from which the insulating film is removed. Subsequently, boron ions are implanted over an entire surface of the device in a concentration that is lower than that of the n-type region and higher than that of the p-type semiconductor region, to a smaller depth than that of the n-type region, and heat treatment is then effected to form a high-concentration boron diffused region in a surface layer of the p-type semiconductor region.

Abstract: A process for forming a structure of a high-frequency bipolar transistor on a layer of a semiconductor material with conductivity of a first type. The process includes forming a first shallow base region by implantation along a selected direction of implantation and using a dopant with a second type of conductivity. The region extends from a first surface of the semiconductor material layer and encloses, toward said first surface, an emitter region with conductivity of the first type. In accordance with the invention, the implantation step includes at least one process phase at which the direction of implantation is maintained at a predetermined angle significantly greatly than zero degrees from the direction of a normal line to said first surface. Preferably, the implantation angle is of about 45 degrees.

Abstract: A process for forming a first bipolar transistor having a single polysilicon structure and a second bipolar transistor having a single polysilicon structure and being of a conducting type opposite to that of the first bipolar transistor on the same substrate. In the process of fabricating a semiconductor device in which a first bipolar transistor having a single polysilicon structure, a second bipolar transistor having a single polysilicon structure and being of a conducting type opposite to that of the first bipolar transistor, and a third bipolar transistor having a double polysilicon structure are provided on the same semiconductor substrate, a base contact portion of the first bipolar transistor and an emitter of the second bipolar transistor are formed in the same step, and an emitter of the first bipolar transistor and base contact portions of the second and third bipolar transistors are formed in the same step.

Abstract: A first photoresist layer has opening portions in a region where an n-channel MOS transistor should be formed and in a region where a collector leading region should be formed. Then, phosphorous is implanted with taking the first photoresist layer as a mask. The first photoresist layer is then removed and a second photoresist layer is formed. The second photoresist layer has opening portions in a region where an emitter region should be formed and in the region where the collector leading region should be formed. Phosphorous is implanted with taking the second photoresist layer as a mask to form an n-type selective diffusion region in a region below the region where the emitter region should be formed and in the region where the collector leading region should be formed. Then, the second photoresist layer is removed. A polycrystalline silicon layer is formed over the entire surface and arsenic is implanted therein to make it n-type.

Abstract: An ultrahigh speed bipolar transistor has a base region which is formed from a P.sup.+ base polysilicon sidewall using a self-alignment method, and a base junction window which is formed in order to minimize the collector-base junction capacity. In the method for fabricating this transistor, an insulation layer of oxide silicon or nitrogen silicon is formed under the base polysilicon layer. Accordingly, impurities from the base polysilicon layer do not diffuse into the epitaxial layer during the diffusion process. Instead, the extrinsic base region is formed by the diffusion of impurities from the polysilicon sidewall which is connected to the base polysilicon layer. Therefore the length of the entire base region is shortened. Furthermore, the junction area between the collector region is also lowered. Thus, the collector-base junction capacity is decreased and a higher operating speed is obtained.

Abstract: A semiconductor device and a method for manufacturing such a device are presented. The type of semiconductor device is one which merges one type of transistor (e.g., bipolar junction transistors) with another type (e.g., CMOS transistors). Specifically, the semiconductor device may comprise a semiconductor substrate and first buried layers of a first conductive and second type buried layers of a second conductive type both formed within the semiconductor substrate. The first buried layers are preferably at a different level within the semiconductor substrate then the level of the second buried layers. First epitaxial layer portions are formed over the first buried layers and second epitaxial layer portions are formed over the second type buried layers. Isolation regions are formed on the first epitaxial layer portions. In forming the semiconductor substrate, photoresists are formed at regular spatial intervals on a substrate.

Abstract: A method of producing the bipolar transistor includes forming an aperture through a triple layer over an active region of an epitaxial layer, then forming a shallow polysilicon film at the bottom of the aperture. An intrinsic base region is formed by segregating a conductive impurity to the epitaxial layer by thermally oxidizing the polysilicon film. Then an extrinsic base region is formed by diffusing impurities into the epitaxial layer from a polysilicon sidewall formed on the aperture. In the transistor fabricated according to this method, an insulation layer of oxide silicon or nitrogen silicon is formed under the base polysilicon layer. Accordingly, impurities from the base polysilicon layer do not diffuse into the epitaxial layer during the diffusion process. Instead, the extrinsic base region is formed by the diffusion of impurities from the polysilicon sidewall which is connected to the base polysilicon layer. Therefore the length of the entire base region is shortened.