Abstract: A method includes providing a single crystal substrate having a buffer layer on a surface of the substrate. The buffer layer provides a transition between the crystallographic lattice structure of the substrate and the crystallographic lattice structure of the semiconductor layer and has its resistivity increased by ion implanting a dopant into the buffer layer; and forming semiconductor layer on the ion implanted buffer layer. The semiconductor layer may be a wide bandgap semiconductor layer having a high electron mobility transistors formed therein.

Abstract: Fabrication of a first device on a substrate is performed by exposing a first device region, removing a portion of the substrate to create a trench in the first device region, forming a screen layer with a first dopant concentration in the trench on the substrate, and forming an epitaxial channel on the screen layer having a first thickness. On or more other devices are similarly formed on the substrate independent of each other with epitaxial channels of different thicknesses than the first thickness. Devices with screen layers having the same dopant concentration but with different epitaxial channel thicknesses have different threshold voltages. Thus, a wide variety of threshold voltage devices can be formed on the same substrate. Further threshold voltage setting can be achieved through variations in the dopant concentration of the screen layers.

Abstract: A first transistor and a second transistor are formed with different threshold voltages. A first gate is formed over the first region of a substrate for a first transistor and a second gate over the second region for a second transistor. The first region is masked. A threshold voltage of the second transistor is adjusted by implanting through the second gate while masking the first region. Current electrode regions are formed on opposing sides of the first gate and current electrode regions on opposing sides of the second gate.

Abstract: A semiconductor device comprises a substrate and first and second stress-generating epitaxial regions on the substrate and spaced apart from each other. A channel region is on the substrate and positioned between the first and second stress-generating epitaxial regions. A gate electrode is on the channel region. The channel region is an epitaxial layer, and the first and second stress-generating epitaxial regions impart a stress on the channel region.

Abstract: An embodiment of a semiconductor power device provided with: a structural body made of semiconductor material with a first conductivity, having an active area housing one or more elementary electronic components and an edge area delimiting externally the active area; and charge-balance structures, constituted by regions doped with a second conductivity opposite to the first conductivity, extending through the structural body both in the active area and in the edge area in order to create a substantial charge balance. The charge-balance structures are columnar walls extending in strips parallel to one another, without any mutual intersections, in the active area and in the edge area.

Abstract: Provided is an image sensor including a drive transistor as a voltage buffer, which can suppress generation of secondary electrons from a channel of the drive transistor to prevent generation of image defects caused by dark current. The transistor includes a gate electrode formed on a substrate, source and drain regions formed in the substrate exposed to both sides of the gate electrode, respectively, and an electric field attenuation region formed on the drain region and partially overlapping the gate electrode.

Abstract: A first transistor includes a first impurity layer of a first conduction type formed in a first region of a semiconductor substrate, a first epitaxial semiconductor layer formed above the first impurity layer, a first gate insulating film formed above the first epitaxial semiconductor layer, a first gate electrode formed above the first gate insulating film, and first source/drain regions of a second conduction type formed in the first epitaxial semiconductor layer and in the semiconductor substrate in the first region.

Abstract: There are disclosed herein various implementations of a semiconductor structure and method. The semiconductor structure comprises a substrate, a transition body over the substrate, and a group III-V intermediate body having a bottom surface over the transition body. The semiconductor structure also includes a group III-V device layer over a top surface of the group III-V intermediate body. The group III-V intermediate body has a continuously reduced impurity concentration wherein a higher impurity concentration at the bottom surface is continuously reduced to a lower impurity concentration at the top surface.

Abstract: In one aspect, a FET device is provided. The FET device includes a substrate; a semiconductor material on the substrate; at least one gate on the substrate surrounding a portion of the semiconductor material that serves as a channel region of the device, wherein portions of the semiconductor material extending out from the gate serve as source and drain regions of the device, and wherein the source and drain regions of the device are displaced from the substrate; a planarizing dielectric on the device covering the gate and the semiconductor material; and contacts which extend through the planarizing dielectric and surround the source and drain regions of the device.

Abstract: A method for a power layout of an integrated circuit. The method includes providing at least one unit power cell. The unit power cell includes at least one power grid cell. Each power grid cell has at least one first power layer configured to be coupled to a high power supply voltage and at least one second power layer configured to be coupled to a lower power supply voltage. The first power layer has conductive lines in at least two different directions and the at least one second power layer has conductive lines in at least two different directions. The method further includes filling a target area in the power layout by at least one unit power cell to implement at least one power cell.

Abstract: In one embodiment, there is an asymmetric multi-gated transistor that has a semiconductor fin with a non-uniform doping profile. A first portion of the fin has a higher doping concentration while a second portion of the fin has a lower doping concentration. In another embodiment, there is an asymmetric multi-gated transistor with gate dielectrics formed on the semiconductor fin that vary in thickness. This asymmetric multi-gated transistor has a thin gate dielectric formed on a first side portion of the semiconductor fin and a thick gate dielectric formed on a second side portion of the fin.

Abstract: Provided is a method of fabricating a semiconductor device. The method includes forming a first III-V family layer over a substrate. The first III-V family layer includes a surface having a first surface morphology. The method includes performing an ion implantation process to the first III-V family layer through the surface. The ion implantation process changes the first surface morphology into a second surface morphology. After the ion implantation process is performed, the method includes forming a second III-V family layer over the first III-V family layer. The second III-V family layer has a material composition different from that of the first III-V family layer.

Abstract: A semiconductor device can include a transistor and an isolation region. The transistor is formed in a semiconductor substrate having a first conductivity type. The transistor includes a drift region extending from a drain region toward a source region and having a second conductivity type. The drift region includes a first resurf region near a working top surface and having the first conductivity type. The high voltage isolation island region includes a first well region laterally offset from the drift region. The first well region has the second conductivity type. An isolation region is located laterally between the drain region and the first well region. The isolation region comprises a portion of the semiconductor substrate extending to the top working surface.

Abstract: Disclosed is a low mismatch semiconductor device that comprises a lightly doped channel region having a first conductivity type and a first dopant concentration in a semiconductor body, and a high-k metal gate stack including a gate metal layer formed over a high-k gate dielectric without having a dielectric cap on the high-k dielectric. The high-k metal gate stack being formed over the lightly doped channel region. The lightly doped channel region may be a P- or N-conductivity region, for example, and may be part of a corresponding P- or N-semiconductor substrate, or a P- or N-well formed in a substrate of the respectively opposite conductivity type. The disclosed semiconductor device, which may be an NMOS or PMOS analog device, for example, can be fabricated as part of an integrated circuit including one or more CMOS logic devices.

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: A method of manufacturing a capacitive transducer by applying a first etching mask on a layer. Applying a second etching mask to define the movable set of fingers, the fixed set of fingers, a body, and springs, and the body is connected to the movable set of fingers and the springs while the movable set of fingers are interdigitated with the fixed set of fingers. Etching the layer and the first etching mask using the second etching mask and removing the second etching mask. Etching the layer such that one of the movable set of fingers and the fixed set of fingers is shorter than the other of the movable set of fingers and the fixed set of fingers. Releasing the body, the springs, and the movable set of fingers using etching, such that, upon applying a force to the body, the body moves parallel to the substrate.

Abstract: A split gate memory cell. First and second well regions of respectively first and second conductivity types are formed in the substrate. A floating gate is disposed on a junction of the first and second well regions and insulated from the substrate. A control gate is disposed over the sidewall of the floating gate and insulated from the substrate and the floating gate and partially extends to the upper surface of the floating gate. A doping region of the first conductivity type is formed in the second well region. The first well region and the doping region respectively serve as source and drain regions of the split gate memory cell.

Abstract: The present disclosure provides a semiconductor device that may include a substrate including a semiconductor layer overlying an insulating layer. A gate structure that is present on a channel portion of the semiconductor layer. A first dopant region is present in the channel portion of the semiconductor layer, in which the peak concentration of the first dopant region is present within the lower portion of the gate conductor and the upper portion of the semiconductor layer. A second dopant region is present in the channel portion of the semiconductor layer, in which the peak concentration of the second dopant region is present within the lower portion of the semiconductor layer.

Abstract: A static RAM cell may be formed on the basis of two double channel transistors and a select transistor, wherein a body contact may be positioned laterally between the two double channel transistors in the form of a dummy gate electrode structure, while a further rectangular contact may connect the gate electrodes, the source regions and the body contact, thereby establishing a conductive path to the body regions of the transistors. Hence, compared to conventional body contacts, a very space-efficient configuration may be established so that bit density in static RAM cells may be significantly increased.

Abstract: A photoelectric conversion device includes a semiconductor substrate, a first insulating film on the semiconductor substrate, a second insulating film on the first insulating film, a third insulating film on the second insulating film, and a wiring disposed in the third insulating film, the wiring being a wiring layer closest to the semiconductor substrate. A first plug of a shared contact structure and a second plug are disposed in the first insulating film. A third plug and a first wiring that constitute a dual damascene structure are disposed in the second and third insulating films. The first insulating film is used as an etching stopper film during etching of the second insulating film and the second insulating film is used as an etching stopper film during etching of the third insulating film.

Abstract: A Schottky diode device is provided, including a p-type semiconductor structure. An n drift region is disposed over the p-type semiconductor structure, wherein the n drift region comprises first and second n-type doping regions having different n-type doping concentrations, and the second n-type doping region is formed with a dopant concentration greater than that in the first n-type doping region. A plurality of isolation structures is disposed in the second n-type doping region of the n drift region, defining an anode region and a cathode region. A third n-type doping region is disposed in the second n-type doping region exposed by the cathode region. An anode electrode is disposed over the first n-type doping region in the anode region. A cathode electrode is disposed over the third n-type doping region in the cathode region.

Abstract: A static RAM cell may be formed on the basis of two double channel transistors and a select transistor, wherein a body contact may be positioned laterally between the two double channel transistors in the form of a dummy gate electrode structure, while a further rectangular contact may connect the gate electrodes, the source regions and the body contact, thereby establishing a conductive path to the body regions of the transistors. Hence, compared to conventional body contacts, a very space-efficient configuration may be established so that bit density in static RAM cells may be significantly increased.

Abstract: An object of the present invention is to prevent the deterioration of a TFT (thin film transistor). The deterioration of the TFT by a BT test is prevented by forming a silicon oxide nitride film between the semiconductor layer of the TFT and a substrate, wherein the silicon oxide nitride film ranges from 0.3 to 1.6 in a ratio of the concentration of N to the concentration of Si.

Abstract: Provided is a method of fabricating a thin film transistor including source and drain electrodes, a novel channel layer, a gate insulating layer, and a gate electrode, which are formed on a substrate. The method includes the steps of forming the channel layer using an oxide semiconductor doped with boron; and patterning the channel layer. The channel layer formed is an oxide semiconductor thin film doped with boron. The electrical characteristics and high temperature stability of the thin film transistor are improved remarkably.

Abstract: A method for and devices utilizing monolithic integration of enhancement-mode and depletion-mode AlGaN/GaN heterojunction field-effect transistors (HFETs) is disclosed. Source and drain ohmic contacts of HFETs are first defined. Gate electrodes of the depletion-mode HFETs are then defined. Gate electrodes of the enhancement-mode HFETs are then defined using fluoride-based plasma treatment and high temperature post-gate annealing of the sample. Device isolation is achieved by either mesa etching or fluoride-based plasma treatment. This method provides a complete planar process for GaN-based integrated circuits favored in high-density and high-speed applications.

Abstract: A semiconductor device, and particularly a high electron mobility transistor (HEMT), having a plurality of epitaxial layers and experiencing an operating (E) field. A negative ion region in the epitaxial layers to counter the operating (E) field. One method for fabricating a semiconductor device comprises providing a substrate and growing epitaxial layers on the substrate. Negative ions are introduced into the epitaxial layers to form a negative ion region to counter operating electric (E) fields in the semiconductor device. Contacts can be deposited on the epitaxial layers, either before or after formation of the negative ion region.

Abstract: This invention describes a method of building complementary logic circuits using junction field effect transistors in silicon. This invention is ideally suited for deep submicron dimensions, preferably below 65 nm. The basis of this invention is a complementary Junction Field Effect Transistor which is operated in the enhancement mode. The speed-power performance of the JFETs becomes comparable with the CMOS devices at sub-70 nanometer dimensions. However, the maximum power supply voltage for the JFETs is still limited to below the built-in potential (a diode drop). To satisfy certain applications which require interface to an external circuit driven to higher voltage levels, this invention includes the structures and methods to build CMOS devices on the same substrate as the JFET devices.

Abstract: A transistor comprises a substrate of a first conductivity type, a drain region and a source region of a second conductivity type, a gate, a gate oxide layer, an adjustment implant region of the first conductivity type and a planar junction. The drain region and the source region are disposed in the substrate. The gate is placed over the substrate between the source region and the drain region. The gate is separated from the substrate by the gate oxide layer. The adjustment implant region is disposed under the gate oxide layer and in the substrate. A second doping concentration of the adjustment implant region is higher than a first doping concentration of the substrate. The adjustment implant region and the drain region in a predetermined shape form the planar junction with a surface curvature pointing towards the drain region to relax electrical field intensity at a location of the planar junction.

Abstract: In a state of a first semiconductor integrated circuit device on which a first semiconductor integrated circuit board including a first mask ROM and a programmable ROM are mounted, an ultimate program determined by using the programmable ROM is stored in a second ROM of a second semiconductor integrated circuit board which is substantially similar in structure to the first semiconductor integrated circuit board, thereby manufacturing a second semiconductor integrated circuit device as an ultimate product.

Abstract: At least one source/drain zone (140, 142, 160, or 162) of an enhancement-mode insulated-gate field-effect transistor (120 or 122) is provided with graded junction characteristics to reduce junction capacitance, thereby increasing switching speed. Each graded junction source/drain zone contains a main portion (140M, 142M, 160M, or 162M) and a more lightly doped lower portion (140L, 142L, 160L, or 162L) underlying, and vertically continuous with, the main portion. The magnitudes of the threshold voltages of a group of such transistors fabricated under the same post-layout fabrication process conditions so as to be of different channel lengths reach a maximum absolute value VTAM when the channel length is at a value LC, are at least 0.03 volt less than VTAM when the channel length is approximately 0.3 ?m greater than LC, and materially decrease with increasing channel length when the channel length is approximately 1.0 ?m greater than LC.

Abstract: An integrated circuit includes at least one photodiode associated with a read transistor. The photodiode is formed from a stack of three semiconductor layers comprising a buried layer, an floating substrate layer and an upper layer. The drain region and/or the source region of the transistor are incorporated within the upper layer. The buried layer is electrically isolated from the upper layer so as to allow the buried layer to be biased independently of the upper layer.

Abstract: Merged P-i-N Schottky device in which the oppositely doped diffusions extend to a depth and have been spaced apart such that the device is capable of absorbing a reverse avalanche energy comparable to a Fast Recovery Epitaxial Diode having a comparatively deeper oppositely doped diffusion region.

Abstract: A method for fabricating MOS-FET using a SOI substrate includes a process of ion implantation of an impurity into a channel region in a SOI layer; and a process of channel-annealing in a non-oxidized atmosphere. In the ion implantation process, a concentration peak of the impurity is made to exist in the SOI layer. Moreover in the channel-annealing process, the impurity is distributed with a high concentration in the vicinity of the surface of the SOI layer under the following condition with the anneal temperature as T (K) and annealing time as t (minutes): 506×1000/T?490<t<400×1000/T?386.

Abstract: Reduced-step CMOS processes for low-cost integrated circuits (ICs) and, more particularly, low-cost radio frequency identification (RFID) devices are disclosed. The CMOS processes disclosed provide sufficient device performance and reliability while reducing the number and complexity of required process steps, thereby reducing the cost for manufacturing ICs. By recognizing the particular needs for low-cost integrated circuits such as RFID devices (for example, reduced needs for performance, power and longevity) and by identifying a reduced set of CMOS process steps, an advantageous solution is achieved for producing low-cost integrated circuits and low-cost RFID devices.

Abstract: A semiconductor device and fabrication method thereof are disclosed. An example semiconductor device includes a semiconductor substrate having a device isolation area defining an active area; a gate oxide layer formed on the active area of the substrate; a gate on the gate oxide layer; a spacer provided to a sidewall of the gate; and a well region provided within the active area. The well region includes a threshold voltage adjustment doped region, a halo region, a source region, a drain region, an additional doped region, and a channel stop region, the additional doped region provided between the well region and each of the source and drain regions.

Abstract: A semiconductor device includes: a first group-III nitride semiconductor layer formed on a substrate; a second group-III nitride semiconductor layer made of a single layer or two or more layers, formed on the first group-III nitride semiconductor layer, and acting as a barrier layer; a source electrode, a drain electrode, and a gate electrode formed on the second group-III nitride semiconductor layer, the gate electrode controlling a current flowing between the source and drain electrodes; and a heat radiation film with high thermal conductivity which covers, as a surface passivation film, the entire surface other than a bonding pad.

Abstract: A MLD-SIMOX wafer is obtained by forming a first ion-implanted layer in a silicon wafer; forming a second ion-implanted layer that is in an amorphous state; and subjecting the wafer to a high-temperature heat treatment to maintain the wafer in an atmosphere containing oxygen at a temperature that is not lower than 1300° C. but lower than a silicon melting point to change the first and the second ion-implanted layers into a BOX layer, wherein the dose amount for the first ion-implanted layer is 1.25 to 1.5×1017 atoms/cm2, the dose amount for the second ion-implanted layer is 1.0×1014 to 1×1016 atoms/cm2, the wafer is preheated to a temperature of 50° C. to 200° C. before forming the second ion-implanted layer, and the second ion-implanted layer is formed in a state where it is continuously heated to a preheating temperature.

Abstract: A semiconductor device suitable for a source-follower circuit, provided with a gate electrode formed on a semiconductor substrate via a gate insulation film, a first conductivity type layer formed in the semiconductor substrate under a conductive portion of the gate electrode and containing a first conductivity type impurity, first source/drain regions of the first conductivity type impurity formed in the semiconductor substrate and extended from edge portions of the gate electrode, and second source/drain regions having a first conductivity type impurity concentration lower than that in the first source/drain regions and formed adjoining the gate insulation film and the first source/drain regions in the semiconductor substrate so as to overlap portions of the conductive portion of the gate electrode.

Abstract: A method for smoothing variations in threshold voltage in an integrated circuit layout. The method begins by identifying recombination surfaces associated with transistors in the layout. Such recombination surfaces are treated to affect the recombination of interstitial atoms adjacent such surfaces, thus minimizing variations in threshold voltage of transistors within the layout.

Abstract: In a state of a first semiconductor integrated circuit device on which a first semiconductor integrated circuit board including a first mask ROM and a programmable ROM are mounted, an ultimate program determined by using the programmable ROM is stored in a second ROM of a second semiconductor integrated circuit board which is substantially similar in structure to the first semiconductor integrated circuit board, thereby manufacturing a second semiconductor integrated circuit device as an ultimate product.

Abstract: A substrate having at least two metal oxide semiconductor devices of a same conductive type and a gap formed between the two devices is provided. A first stress layer is formed over the substrate to cover the metal-oxide semiconductor devices and the substrate, filling the gap. An etching back process is then performed to remove a portion of the stress material layer inside the gap. A second stress layer and a dielectric layer are sequentially formed on the first stress layer. The first stress layer and the second stress layer provide a same type of stress. A portion of the second stress layer is removed to form a contact opening. A second conductive layer is filled into the contact opening to form a contact.

Abstract: Reduced leakage current field-effect transistors and fabrication methods. Semiconductor device including substrate of first conductivity type, first well and second well of second conductivity type in substrate, channel of second conductivity type between first well and second well in substrate, and gate region of first conductivity type within channel, wherein gate region is electrically operable to modulate depletion width of channel. First well may be a drain region and the second well may be a source region. Channel includes first link region between gate region and first well or drain region and second link region between the gate region and second well or source region; wherein first link region is of second conductivity type of at least two doping densities. First link region is higher doped in a portion adjacent to drain region than in another portion adjacent to gate region. Method of fabricating a reduced leakage current FET.

Abstract: A method of forming a contact is provided. A substrate having at least two metal oxide semiconductor devices is provided and a gap is formed between the two devices. A first stress layer is formed over the substrate to cover the metal-oxide semiconductor devices and the substrate. The first stress layer is formed by first forming a first stress material layer over the substrate to cover the metal-oxide semiconductor devices and to fill the gap, the stress material inside the gap. An etching back process is then performed to remove a portion of the stress material layer inside the gap. A second stress layer and a dielectric layer are sequentially formed on the first stress layer. A portion of the second stress layer is removed to form a contact opening. A first conductive layer is filled into the contact opening to form a contact.

Abstract: Embodiments relate to a method for manufacturing a semiconductor device. According to embodiments, a gate insulating layer and a conductive layer may be formed on a semiconductor substrate. The conductive layer may be selectively etched to form a relatively thick portion of the conductive layer in a gate region and relatively thin portions of the conductive layer in other regions. Impurity ions may be implanted in an entire surface of the semiconductor substrate to form a lightly doped drain region. The gate insulating layer and the conductive layer may be selectively etched to form a gate electrode. Insulating layer sidewalls may be formed at both sides of the gate electrode, and source/drain regions may be formed in portions of the semiconductor substrate located at both sides of the gate electrode.

Abstract: A junction leak current of a transistor including a silicide layer provided on a source/drain region is to be suppressed. After forming a gate electrode over a chip-side surface of a silicon substrate, an insulating layer is formed over the gate electrode. The insulating layer is etched back so as to form a sidewall that covers the sidewall of the gate electrode, and a region adjacent to the sidewall on the chip-side surface of the silicon substrate, where a source/drain region is to be formed, is etched so as to form a generally horizontal scraped section on the chip-side surface. Then a dopant is implanted to the silicon substrate around the gate electrode, to thereby form the source/drain region. On the chip-side surface of the silicon substrate where the gate electrode is provided, a Ni layer is formed, so that the Ni layer is reacted with the silicon substrate thus to form a Ni-silicide layer.

Abstract: A MESFET and method for fabricating a MESFET are provided. The method includes forming an n-type channel portion in a substrate and forming a p-type channel portion in the substrate. A boundary of the n-type channel portion and a boundary of the p-type channel portion define an intrinsic region in the substrate.

Abstract: A dopant gradient region of a first conductivity type and a corresponding channel impurity gradient below a transfer gate and adjacent a charge collection region of a CMOS imager photodiode are disclosed. The channel impurity gradient in the transfer gate provides a complete charge transfer between the charge collection region of the photodiode and a floating diffusion node. The dopant gradient region is formed by doping a region at one end of the channel with a low enhancement dopant and another region at the other end of the channel with a high enhancement dopant.

Abstract: A dopant gradient region of a first conductivity type and a corresponding channel impurity gradient below a transfer gate and adjacent a charge collection region of a CMOS imager photodiode are disclosed. The channel impurity gradient in the transfer gate provides a complete charge transfer between the charge collection region of the photodiode and a floating diffusion node. The dopant gradient region is formed by doping a region at one end of the channel with a low enhancement dopant and another region at the other end of the channel with a high enhancement dopant.

Abstract: An integrated circuit structure, a trigger device and a method of electrostatic discharge protection, the integrated circuit structure including: a substrate having a top surface defining a horizontal direction, the substrate of a first dopant type; a first horizontal layer in the substrate, the first layer of a second dopant type; and a second horizontal layer of the first dopant type, the second layer on top of the first layer and between the top surface of the substrate and the first layer, the second layer electrically modulated by the first layer.

Abstract: A semiconductor device may include a channel region formed between a source and a drain region. One or more first pockets may be formed in the channel region adjacent to junctions. The first pockets may be doped with a dopant of the first conductivity type. At least one second pocket may be formed adjacent to each of the junctions and stacked against each of the first pockets. The second pocket may be doped with a dopant of a second conductivity type such that the dopant concentration in the second pocket is less than the dopant concentration in the first pockets. The second pocket may reduce a local substrate concentration without changing the conductivity type of the channel region.