Abstract: A semiconductor device including a channel region formed in a semiconductor substrate; a source region formed on one side of the channel region; a drain region formed on the other side of the channel region; a gate electrode formed on the channel region with a gate insulating film therebetween; and a stress-introducing layer that applies stress to the channel region, the semiconductor device having a stress distribution in which source region-side and drain region-side peaks are positioned between a pn junction boundary of the channel region and the source region and a pn junction boundary of the channel region and the drain region.

Abstract: Methods according to the present disclosure include: providing a substrate including: a first semiconductor region, a second semiconductor region, and a trench isolation (TI) laterally between the first and second semiconductor regions; forming an epitaxial layer on at least the first semiconductor region of the substrate, wherein the epitaxial layer includes a first semiconductor base material positioned above the first semiconductor region of the substrate; forming an insulator region on at least the first semiconductor base material, the trench isolation (TI), and the second semiconductor region; forming a first opening in the insulator over the second semiconductor region; and growing a second semiconductor base material in the first opening, wherein a height of the second semiconductor base material above the substrate is greater than a height of the first semiconductor base material above the substrate.

Abstract: Methods of according to the present disclosure can include: providing a substrate including: a first semiconductor region, a second semiconductor region, and a trench isolation (TI) laterally between the first and second semiconductor regions; forming a seed layer on the TI and the second semiconductor region of the substrate, leaving the first semiconductor region of the substrate exposed; forming an epitaxial layer on the substrate and the seed layer, wherein the epitaxial layer includes: a first semiconductor base material positioned above the first semiconductor region of the substrate, and an extrinsic base region positioned above the seed layer; forming an opening within the extrinsic base material and the seed layer to expose an upper surface of the second semiconductor region; and forming a second semiconductor base material in the opening.

Abstract: Lateral PNP bipolar junction transistors, methods for fabricating lateral PNP bipolar junction transistors, and design structures for a lateral PNP bipolar junction transistor. An emitter and a collector of the lateral PNP bipolar junction transistor are comprised of p-type semiconductor material that is formed by a selective epitaxial growth process. The source and drain each directly contact a top surface of a device region used to form the emitter and collector. A base contact may be formed on the top surface and overlies an n-type base defined within the device region. The emitter is laterally separated from the collector by the base contact. Another base contact may be formed in the device region that is separated from the other base contact by the base.

Abstract: An example embodiment is a complementary transistor inverter circuit. The circuit includes a semiconductor-on-insulator (SOI) substrate, a lateral PNP bipolar transistor fabricated on the SOI substrate, and a lateral NPN bipolar transistor fabricated on the SOI substrate. The lateral PNP bipolar transistor includes a PNP base, a PNP emitter, and a PNP collector. The lateral NPN bipolar transistor includes a NPN base, a NPN emitter, and a NPN collector. The PNP base, the PNP emitter, the PNP collector, the NPN base, the NPN emitter, and the NPN collector abut the buried insulator of the SOI substrate.

Abstract: The disclosure provides a semiconductor device and method of manufacture therefore. The method for manufacturing the semiconductor device, in one embodiment, includes providing a substrate (210) having a PMOS device region (220) and NMOS device region (260). Thereafter, a first gate structure (240) and a second gate structure (280) are formed over the PMOS device region and the NMOS device region, respectively. Additionally, recessed epitaxial SiGe regions (710) may be formed in the substrate on opposing sides of the first gate structure. Moreover, first source/drain regions may be formed on opposing sides of the first gate structure and second source/drain regions on opposing sides of the second gate structure. The first source/drain regions and second source/drain regions may then be annealed to form activated first source/drain regions (1110) and activated second source/drain regions (1120), respectively.

Abstract: An example embodiment is a complementary transistor inverter circuit. The circuit includes a semiconductor-on-insulator (SOI) substrate, a lateral PNP bipolar transistor fabricated on the SOI substrate, and a lateral NPN bipolar transistor fabricated on the SOI substrate. The lateral PNP bipolar transistor includes a PNP base, a PNP emitter, and a PNP collector. The lateral NPN bipolar transistor includes a NPN base, a NPN emitter, and a NPN collector. The PNP base, the PNP emitter, the PNP collector, the NPN base, the NPN emitter, and the NPN collector abut the buried insulator of the SOI substrate.

Abstract: A structure and method of fabrication thereof relate to a Deeply Depleted Channel (DDC) design, allowing CMOS based devices to have a reduced ?VT compared to conventional bulk CMOS and can allow the threshold voltage VT of FETs having dopants in the channel region to be set much more precisely. The DDC design also can have a strong body effect compared to conventional bulk CMOS transistors, which can allow for significant dynamic control of power consumption in DDC transistors. The semiconductor structure includes an analog device and a digital device each having an epitaxial channel layer where a single gate oxidation layer is on the epitaxial channel layer of NMOS and PMOS transistor elements of the digital device and one of a double and triple gate oxidation layer is on the epitaxial channel layer of NMOS and PMOS transistor elements of the analog device.

Abstract: An IC has cells placed in a cell row having a UTBOX-FDSOI pMOSFET including a ground beneath the pMOS, and an n-doped well beneath it and configured to apply a potential thereto, and a UTBOX-FDSOI nMOSFET including a ground beneath the nMOS, and a p-doped well beneath the ground and configured to apply a potential thereto, and cells, each including a UTBOX-FDSOI pMOSFET including a ground beneath the pMOS, and a p-doped well beneath the ground and configured to apply an electrical potential to the ground, and a UTBOX-FDSOI nMOSFET including a ground beneath the nMOS, and an n-doped well beneath the ground and configured to apply a potential thereto. The cells are placed so that pMOS's of standard cells belonging to a row align along it and a transition cell including a another well and contiguous with first row standard cells thus ensuring continuity with wells of those cells.

Abstract: A structure, method and system for complementary strain fill for integrated circuit chips. The structure includes a first region of an integrated circuit having multiplicity of n-channel and p-channel field effect transistors (FETs); a first stressed layer over n-channel field effect transistors (NFETs) of the first region, the first stressed layer of a first stress type; a second stressed layer over p-channel field effect transistors (PFETs) of the first region, the second stressed layer of a second stress type, the second stress type opposite from the first stress type; and a second region of the integrated circuit, the second region not containing FETs, the second region containing first sub-regions of the first stressed layer and second sub-regions of the second stressed layer.

Abstract: An asymmetric silicon-on-insulator (SOI) junction field effect transistor (JFET) and a method. The JFET includes a bottom gate on an insulator layer, a channel region on the bottom gate and, on the channel region, source/drain regions and a top gate between the source/drain regions. STIs isolate the source/drain regions from the top gate and a DTI laterally surrounds the JFET to isolate it from other devices. Non-annular well(s) are positioned adjacent to the channel region and bottom gate (e.g., a well having the same conductivity type as the top and bottom gates can be connected to the top gate and can extend down to the insulator layer, forming a gate contact on only a portion of the channel region, and/or another well having the same conductivity type as the channel and source/drain regions can extend from the source region to the insulator layer, forming a source-to-channel strap).

Abstract: The present disclosure provides a method including forming STI features in a silicon substrate, defining a first and a second active regions for a PFET and an NFET, respectively; forming a hard mask having an opening to expose the silicon substrate within the first active region; etching the silicon substrate through the opening to form a recess within the first active region; growing a SiGe layer in the recess such that a top surface of the SiGe layer within the first active region and a top surface of the silicon substrate within the second active region are substantially coplanar; forming metal gate material layers; patterning the metal gate material layers to form a metal gate stack on the SiGe layer within the first active region; and forming an eSiGe S/D stressor distributed in both the SiGe layer and the silicon substrate within the first active region.

Abstract: An example embodiment is a complementary transistor inverter circuit. The circuit includes a semiconductor-on-insulator (SOI) substrate, a lateral PNP bipolar transistor fabricated on the SOI substrate, and a lateral NPN bipolar transistor fabricated on the SOI substrate. The lateral PNP bipolar transistor includes a PNP base, a PNP emitter, and a PNP collector. The lateral NPN bipolar transistor includes a NPN base, a NPN emitter, and a NPN collector. The PNP base, the PNP emitter, the PNP collector, the NPN base, the NPN emitter, and the NPN collector abut the buried insulator of the SOI substrate.

Abstract: A fabricating method of CMOS transistor includes following steps. A first gate and a second gate are formed on a substrate. A gate insulator is formed on the substrate to cover the first and second gates. A first source, a first drain, a second source, and a second drain are formed on the gate insulator. The first source and the first drain are above the first gate. The second source and the second drain are above the second gate. A first channel layer and a mask layer are formed on the gate insulator. The mask layer is on the first channel layer. The first channel layer is above the first gate and contacts with the first source and the first drain. A second channel layer is formed on the gate insulator. The second channel layer is above the second gate and contacts with the second source and the second drain.

Abstract: A bipolar transistor (101) has a base (243) formed with an intrinsic base portion (2431), a base contact portion (245C), and a base link portion (243L) that extends between the intrinsic base portion and the base contact portion. An isolating dielectric layer (267-1 or 267-2) is provided above the base link portion. The length of the base link portion is determined, and thereby controlled, with a lateral spacing portion (269-1 or 269-2) of largely non-monocrystalline semiconductor material, preferably polycrystalline semiconductor material, provided on the dielectric layer above the base link portion. The lateral spacing portion is typically provided as part of a layer of non-monocrystalline semiconductor material used in the gate electrode of an insulated-gate field-effect transistor.

Abstract: The present disclosure provides a method including forming STI features in a silicon substrate, defining a first and a second active regions for a PFET and an NFET, respectively; forming a hard mask having an opening to expose the silicon substrate within the first active region; etching the silicon substrate through the opening to form a recess within the first active region; growing a SiGe layer in the recess such that a top surface of the SiGe layer within the first active region and a top surface of the silicon substrate within the second active region are substantially coplanar; forming metal gate material layers; patterning the metal gate material layers to form a metal gate stack on the SiGe layer within the first active region; and forming an eSiGe S/D stressor distributed in both the SiGe layer and the silicon substrate within the first active region.

Abstract: An ESD protection device is provided. The ESD protection device comprises an SCR and an ESD detection circuit. The SCR is coupled between a high voltage and a ground and has a special semiconductor structure which saves area. When the ESD detection circuit detects an ESD event, the ESD detection circuit drives the SCR to provide a discharging path.

Abstract: A semiconductor device with improved transistor operating and flicker noise characteristics includes a substrate, an analog NMOS transistor and a compressively-strained-channel analog PMOS transistor disposed on the substrate. The device also includes a first etch stop liner (ESL) and a second ESL which respectively cover the NMOS transistor and the PMOS transistor. The relative measurement of flicker noise power of the NMOS and PMOS transistors to flicker noise power of reference unstrained-channel analog NMOS and PMOS transistors at a frequency of 500 Hz is less than 1.

Abstract: A semiconductor device including semiconductor material having a bend and a trench feature formed at the bend, and a gate structure at least partially disposed in the trench feature. A method of fabricating a semiconductor structure including forming a semiconductor material with a trench feature over a layer, forming a gate structure at least partially in the trench feature, and bending the semiconductor material such that stress is induced in the semiconductor material in an inversion channel region of the gate structure.

Abstract: A semiconductor structure contains a bipolar transistor (101) and a spacing structure (265-1 or 265-2). The transistor has an emitter (241), a base (243), and a collector (245). The base is formed with an intrinsic base portion (243I), a base link portion (243L), and a base contact portion (245C). The intrinsic base portion is situated below the emitter and above material of the collector. The base link portion extends between the intrinsic base portion and the base contact portions. The spacing structure includes an isolating dielectric layer (267-1 or 267-2) and a spacing component. The dielectric layer extends along the upper semiconductor surface. The spacing component includes a lateral spacing portion (269-1 or 269-2) of largely non-monocrystalline semiconductor material, preferably polycrystalline semiconductor material, situated on the dielectric layer above the base link portion.

Abstract: A MOSFET on SOI device includes an upper region having at least one first MOSFET type semi-conductor device formed on a first semi-conductor layer stacked on a first dielectric layer, a first conductive layer and a first portion of a second semi-conductor layer. A lower region includes at least one second MOSFET type semi-conductor device formed on a second portion of the second semi-conductor layer, a gate of the second semi-conductor device being formed by at least one conductive portion. The second semi-conductor layer is arranged on a second dielectric layer stacked on a second conductive layer.

Abstract: A method of fabricating a CMOS thin film transistor includes: providing a substrate; forming an amorphous silicon layer on the substrate; performing a first annealing process on the substrate and crystallizing the amorphous silicon layer into a polysilicon layer; patterning the polysilicon layer to form first and second semiconductor layers; implanting first impurities into the first and second semiconductor layers; implanting second impurities into the first or second semiconductor layer; and performing a second annealing process on the semiconductor layers to remove the metal catalyst remaining in the first or second semiconductor layer, on which the second impurities are implanted, wherein the first impurities are implanted at a dose of 6×1013/cm2 to 5×1015/cm2, and the second impurities are implanted at a dose of 1×1011/cm2 to 3×1015/cm2.

Abstract: A semiconductor process and apparatus includes forming PMOS transistors (90) with enhanced hole mobility in the channel region by forming a hydrogen-rich silicon nitride layer (91, 136) on or adjacent to sidewalls of the PMOS gate structure as either a hydrogen-rich implant sidewall spacer (91) or as a post-silicide hydrogen-rich implant sidewall spacer (136), where the hydrogen-rich dielectric layer acts as a hydrogen source for passivating channel surface defectivity under the PMOS gate structure.

Abstract: The present invention relates to a semiconductor device comprising a homojunction or a heterojunction with a controlled dopant (concentration) profile and a method of making the same. Accordingly, one aspect of the invention is a method for manufacturing a junction comprising forming a first semiconductor material comprising a first dopant having a first concentration and thereupon; forming a second semiconductor material comprising a second dopant, having a second concentration thereby forming a junction, and depositing by Atomic Layer Epitaxy or Vapor Phase Doping at least a fraction of a monolayer of a precursor suitable to form the second dopant on the first semiconductor material, prior to forming the second semiconductor material, thereby increasing the second concentration of the second dopant at the junction.

Abstract: The invention relates to a semiconductor structure and method of manufacturing and more particularly to a CMOS device with at least one embedded SiGe layer in the source/drain region of the PFET, and at least one embedded SiGe layer in the channel region of the NFET. In one embodiment, the structure of the invention enhances the electron mobility in the NFET device, and further enhances the hole mobility in the PFET device. Additionally, by using the fabrication methods and hence achieving the final structure of the invention, it is also possible to construct a PFET and NFET each with embedded SiGe layers on the same substrate.

Abstract: One aspect of the inventors' concept relates to a method of forming a semiconductor device. In this method, a gate structure is formed over a semiconductor body. A source/drain mask is patterned over the semiconductor body implanted source and drain regions are formed that are associated with the gate structure. After forming the implanted source and drain regions, a multi-stage implant is performed on the source and drain regions that comprises at least two implants where the dose and energy of the first implant varies from the dose and energy of the second implant. Other methods and devices are also disclosed.

Abstract: A poly-emitter type bipolar transistor includes a buried layer formed over an upper portion of a semiconductor substrate, an epitaxial layer formed on the semiconductor substrate, a collector area formed on the epitaxial layer and connected to the buried layer, a base area formed at a part of an upper portion of the epitaxial layer, and a poly-emitter area formed on a surface of the semiconductor substrate in the base area and including a polysilicon material. A BCD device includes a poly-emitter type bipolar transistor having a poly-emitter area including a polysilicon material and at least one of a CMOS and a DMOS formed on a single wafer together with the poly-emitter type bipolar transistor.

Abstract: The present invention provides a method of fabricating an integrated circuit comprising at least one bipolar transistor and at least one field effect transistor. The method includes implanting a dopant species of a first type in a semiconductor layer that is doped with a dopant of a second type opposite the first type to form at least one sinker that contacts at least one collector of said at least one bipolar transistor. The method also includes applying heat to cause the dopant species to diffuse outwards to form at least one doped extension of said at least one sinker and forming said at least one field effect transistor in the doped extension.

Abstract: A semiconductor device fabricating method is described. The semiconductor device fabricating method comprises forming an epitaxial layer on a substrate, wherein the epitaxial layer is the same conductive type as the substrate. A first doped region having the different conductive type from the epitaxial layer is formed in the epitaxial layer. An annealing process is performed to diffuse dopants in the first doped region. A second doped region and an adjacent third doped region are formed in the first doped region. The second doped region is a different conductive type from that of the first doped region, and the third doped region is the same conductive type as that of the first doped region. A gate structure is formed on the epitaxial layer covering a portion of the second and the third doped regions.

Abstract: An integrated circuit arrangement and fabrication method is provided. The integrated circuit arrangement contains an NPN transistor and a PNP transistor. The PNP transistor contains an emitter connection region and a cutout. The cutout delimits the width of the emitter connection region. The electrically conductive material of the connection region laterally overlaps the cutout.

Abstract: An electrostatic discharge (ESD) protection circuit includes a triggering diode that includes a junction between a P-grade (PG) region and an N-well. The PG region has a dopant profile equivalent to a P-drain dopant profile of a PMOS transistor having a breakdown voltage represented by V whereby the triggering diode for conducting a current when a voltage greater than the breakdown voltage V is applied. In an exemplary embodiment, the dopant profile of the PG region includes two dopant implant profiles that include a shallow implant profile with a higher dopant concentration and a deep implant profile with a lower dopant concentration.

Abstract: According to one exemplary embodiment, a method for forming an NPN and a vertical PNP device on a substrate comprises forming an insulating layer over an NPN region and a PNP region of the substrate. The method further comprises forming a buffer layer on the insulating layer and forming an opening in the buffer layer and the insulating layer in the NPN region, where the opening exposes the substrate. The method further comprises forming a semiconductor layer on the buffer layer and in the opening in the NPN region, where the semiconductor layer has a first portion situated in the opening and a second portion situated on the buffer layer in the PNP region. The first portion of the semiconductor layer forms a single crystal base of the NPN device and the second portion of the semiconductor layer forms a polycrystalline emitter of the vertical PNP device.

Abstract: Disclosed are techniques that teach the replacement of the typical organic, plastic, or ceramic package substrate used in semiconductor package devices with a low-CTE package substrate. In one embodiment, a semiconductor device implementing the disclosed techniques is provided, where the device comprises an integrated circuit chip having at least one coupling component formed on an exterior surface thereof. Also, the device includes a package substrate having a mounting surface with bonding pads that are configured to receive the at least one coupling component. In such embodiments, the package substrate is selected or manufactured such that it has a coefficient of thermal expansion in a direction perpendicular to its mounting surface that is less than approximately twice a coefficient of thermal expansion along a plane parallel to its mounting surface.

Abstract: A semiconductor integrated circuit includes an n-channel MOS transistor and a p-channel MOS transistor formed respectively in first and second device regions of a substrate, the n-channel MOS transistor including a first gate electrode carrying sidewall insulation films on respective sidewall surfaces thereof, the p-channel MOS transistor including a second gate electrode carrying sidewall insulation films on respective sidewall surfaces thereof, wherein there is provided a stressor film on the substrate over the first and second device regions such that the stressor film covers the first gate electrode including the sidewall insulation films thereof and the second gate electrode including the sidewall insulation films thereof, wherein the stressor film has a decreased film thickness in the second device region at least in the vicinity of a base part of the second gate electrode.

Abstract: A floating node structure of a CMOS image sensor disposed in a floating node region defined by an isolation structure of a substrate is described. The floating node structure comprises an n-doped region within the floating node region, a p-well surrounding the periphery and the bottom of the n-doped region in the substrate within the folating node region, a surface passivation layer disposed at least on the surface of the p-well, and a contact plug coupling the n-doped region to a source follower transistor of the CMOS image sensor.

Abstract: A semiconductor device manufacturing method including forming at least a first conductive film and a first insulting film above a semiconductor substrate, forming a plurality of first resist patterns above the first insulating film periodically at first intervals, patterning at least the first insulting film by use of the first resist patterns to form a plurality of mask patterns, each of the mask patterns including the first insulating film, selectively forming a second resist pattern in a space between the mask patterns in such a manner that the second resist pattern is formed in the space corresponding to a region where a second wiring structure wider than the first wiring structure is to be formed, and patterning the first conductive film by use of the second resist pattern and the mask patterns.

Abstract: A method is for manufacturing a microeletromechanical system resonator having a semiconductor device and a microelectromechanical system structure unit formed on a substrate. The method includes: forming a lower electrode of an oxide-nitride-oxide capacitor unit included in the semiconductor device using a first silicon layer; forming, using a second silicon layer, a substructure of the microelectromechanical system structure unit and an upper electrode of the oxide-nitride-oxide capacitor unit included in the semiconductor device; and forming, using a third silicon layer, a superstructure of the microelectromechanical system structure unit and a gate electrode of a complementary metal oxide semiconductor circuit unit included in the semiconductor device.

Abstract: Integrated circuit devices are provided including an integrated circuit substrate and first, second and third spaced apart insulating regions in the integrated circuit substrate that define first and second active regions. A first gate electrode is provided on the first active region. The first gate electrode has a first portion on the first active region that extends onto the first insulating region and a second portion at an end of the first portion on the first insulating region. A second gate electrode is provided on the second active region. An insulating layer is provided on the first, second and third active regions defining a first gate contact hole that exposes at least a portion of the second portion of the first gate electrode. The first gate electrode is free of a gate contact hole on the first portion of the first gate electrode. A second gate contact hole is provided on the second active region that exposes at least a portion of the second gate electrode.

Abstract: An interfacial oxide layer (185) is formed in the emitter regions of the NPN transistor (280, 220) and the PNP transistor (290, 200). Fluorine is selectively introduced into the polysilicon emitter region of the NPN transistor (220) to reduce the 1/f noise in the NPN transistor.