Abstract: A semiconductor device is described, which includes a first transistor, a second transistor, and a capacitor. The second transistor and the capacitor are provided over the first transistor so as to overlap with a gate of the first transistor. A semiconductor layer of the second transistor and a dielectric layer of the capacitor are directly connected to the gate of the first transistor. The second transistor is a vertical transistor, where its channel direction is perpendicular to an upper surface of a semiconductor layer of the first transistor.

Abstract: Embodiments of the present invention describe a epitaxial region on a semiconductor device. In one embodiment, the epitaxial region is deposited onto a substrate via cyclical deposition-etch process. Cavities created underneath the spacer during the cyclical deposition-etch process are backfilled by an epitaxial cap layer. The epitaxial region and epitaxial cap layer improves electron mobility at the channel region, reduces short channel effects and decreases parasitic resistance.

Abstract: A memory array and a method for preparing the memory are provided. The memory array includes a semiconductor substrate, an isolation structure and contact enhancement sidewall spacers. The semiconductor substrate has a trench defining laterally separate active areas formed of surface regions of the semiconductor substrate. Top surfaces of a first group of the active areas are recessed with respect to top surfaces of a second group of the active areas. The isolation structure is filled in the trench and in lateral contact with bottom portions of the active areas. The contact enhancement sidewall spacers laterally surround top portions of the active areas, respectively.

Abstract: Methods and devices for low-temperature deposition of phosphorous-doped silicon layers. Disilane is used as a silicon precursor, and nitrogen or a noble gas is used as a carrier gas. Phosphine is a suitable phosphorous precursor.

Abstract: A method for preparing the memory are provided. The method includes forming a trench at a front side of a semiconductor substrate, wherein the trench defines laterally separate active areas formed of surface regions of the semiconductor substrate; filling an isolation structure in the trench, wherein the isolation structure is filled to a height lower than top surfaces of the active areas; recessing a first group of the active areas from top surfaces of the first group of the active areas, while having top surfaces of a second group of the active areas covered; and forming contact enhancement sidewall spacers to laterally surround top portions of the active areas, respectively.

Abstract: A device structure with multiple layers of low temperature epitaxy is disclosed that eliminates source and drain and extension implants, providing a planar interface with abrupt junctions between epitaxial extensions and substrate, mitigating electrostatic coupling between transistor drain and transistor channel and reducing short channel effects. The reduction of channel doping results in improved device performance from reduced impurity scattering and reduction of random dopant induced threshold voltage variations (sigma-Vt). Avoiding implants further reduces device sigma-Vt due to random dopants' diffusion from source and drain extensions, which creates device channel length variations during thermal activation anneal of implanted dopants. The defined transistor structure employs at least two levels of low-temperature epitaxy, and creates a planar interface with various types of transistor substrates resulting in performance improvement.

Abstract: A vertical fin field effect transistor including a doped region in a substrate, wherein the doped region has the same crystal orientation as the substrate, a first portion of a vertical fin on the doped region, wherein the first portion of the vertical fin has the same crystal orientation as the substrate and a first portion width, a second portion of the vertical fin on the first portion of the vertical fin, wherein the second portion of the vertical fin has the same crystal orientation as the first portion of the vertical fin, and the second portion of the vertical fin has a second portion width less than the first portion width, a gate structure on the second portion of the vertical fin, and a source/drain region on the top of the second portion of the vertical fin.

Abstract: A high electron mobility transistor includes a set of electrodes, such as a source, a drain, a top gate, and a side gate, and includes a semiconductor structure having a fin extending between the source and the drain. The top gate is arranged on top of the fin, and the side gate is arranged on a sidewall of the fin at a distance from the top gate. The semiconductor structure includes a cap layer positioned beneath the top gate and a channel layer arranged beneath the cap layer for providing electrical conduction. The cap layer includes nitride-based semiconductor material to enable a heterojunction forming a carrier channel between the source and the drain.

Abstract: A multi-gate transistor includes a semiconductor fin over a substrate. The semiconductor fin includes a central fin formed of a first semiconductor material; and a semiconductor layer having a first portion and a second portion on opposite sidewalls of the central fin. The semiconductor layer includes a second semiconductor material different from the first semiconductor material. The multi-gate transistor further includes a gate electrode wrapping around sidewalls of the semiconductor fin; and a source region and a drain region on opposite ends of the semiconductor fin. Each of the central fin and the semiconductor layer extends from the source region to the drain region.

Abstract: The present disclosure provides a semiconductor device. The semiconductor device includes a substrate having isolation regions, a gate region, source and drain regions separated by the gate region, a first fin structure in a gate region. The first fin structure includes a first semiconductor material layer as a lower portion of the first fin structure, a semiconductor oxide layer as an outer portion of a middle portion of the first fin structure, the first semiconductor material layer as a center portion of the middle portion of the first fin structure and a second semiconductor material layer as an upper portion of the first fin structure. The semiconductor device also includes a source/drain feature over the substrate in the source/drain region between two adjacent isolation regions and a high-k (HK)/metal gate (MG) stack in the gate region, wrapping over a portion of the first fin structure.

Abstract: Embodiments of the present disclosure describe apparatuses, methods, and systems of an integrated circuit (IC) device. The IC device may include a buffer layer disposed on a substrate, the buffer layer including gallium (Ga) and nitrogen (N) and a barrier layer disposed on the buffer layer, the barrier layer including aluminum (Al) and nitrogen (N). The IC device may further include a gate terminal and a gate dielectric layer disposed between the gate terminal and the barrier layer and/or between the gate terminal and the buffer layer. In various embodiments, the gate dielectric layer may include a fluoride- or chloride-based compound, such as calcium fluoride (CaF2).

Abstract: Semiconductor trilayer structures that are doped and strained are provided. Also provided are mechanically flexible transistors, including radiofrequency transistors, incorporating the trilayer structures and methods for fabricating the trilayer structures and transistors. The trilayer structures comprise a first layer of single-crystalline semiconductor material, a second layer of single-crystalline semiconductor material and a third layer of single-crystalline semiconductor material. In the structures, the second layer is in contact with and sandwiched between the first and third layers and the first layer is selectively doped to provide one or more doped regions in the layer.

Abstract: Techniques are disclosed for incorporating high mobility strained channels into fin-based transistors (e.g., FinFETs such as double-gate, trigate, etc), wherein a stress material is cladded onto the channel area of the fin. In one example embodiment, silicon germanium (SiGe) is cladded onto silicon fins to provide a desired stress, although other fin and cladding materials can be used. The techniques are compatible with typical process flows, and the cladding deposition can occur at a plurality of locations within the process flow. In some cases, the built-in stress from the cladding layer may be enhanced with a source/drain stressor that compresses both the fin and cladding layers in the channel. In some cases, an optional capping layer can be provided to improve the gate dielectric/semiconductor interface. In one such embodiment, silicon is provided over a SiGe cladding layer to improve the gate dielectric/semiconductor interface.

Abstract: A semiconductor device having epitaxial structures includes a gate structure positioned on a substrate, epitaxial structures formed in the substrate at two sides of the gate structure, and an undoped cap layer formed on the epitaxial structures. The epitaxial structures include a dopant, a first semiconductor material having a first lattice constant, and a second semiconductor material having a second lattice constant, and the second lattice constant is larger than the first lattice constant. The undoped cap layer also includes the first semiconductor material and the second semiconductor material. The second semiconductor material in the epitaxial structures includes a first concentration, the second semiconductor material in the undoped cap layer includes at least a first concentration, and the second concentration is lower than the first concentration.

Abstract: The present disclosure involves an apparatus. The apparatus includes a substrate having a front side a back side opposite the front side. The substrate includes a plurality of openings formed from the back side of the substrate. The openings collectively define a pattern on the back side of the substrate from a planar view. In some embodiments, the substrate is a silicon substrate or a silicon carbide substrate. Portions of the silicon substrate vertically aligned with the openings have vertical dimensions that vary from about 100 microns to about 300 microns. A III-V group compound layer is formed over the front side of the silicon substrate. The III-V group compound layer is a component of one of: a light-emitting diode (LED), a laser diode (LD), and a high-electron mobility transistor (HEMT).

Abstract: A semiconductor device includes a channel region; a gate dielectric over the channel region; a gate electrode over the gate dielectric; and a first source/drain region adjacent the gate dielectric. The first source/drain region is of a first conductivity type. At least one of the channel region and the first source/drain region includes a superlattice structure. The semiconductor device further includes a second source/drain region on an opposite side of the channel region than the first source/drain region. The second source/drain region is of a second conductivity type opposite the first conductivity type. At most, one of the first source/drain region and the second source/drain region comprises an additional superlattice structure.

Abstract: Techniques are disclosed for incorporating high mobility strained channels into fin-based transistors (e.g., FinFETs such as double-gate, trigate, etc), wherein a stress material is cladded onto the channel area of the fin. In one example embodiment, silicon germanium (SiGe) is cladded onto silicon fins to provide a desired stress, although other fin and cladding materials can be used. The techniques are compatible with typical process flows, and the cladding deposition can occur at a plurality of locations within the process flow. In some cases, the built-in stress from the cladding layer may be enhanced with a source/drain stressor that compresses both the fin and cladding layers in the channel. In some cases, an optional capping layer can be provided to improve the gate dielectric/semiconductor interface. In one such embodiment, silicon is provided over a SiGe cladding layer to improve the gate dielectric/semiconductor interface.

Abstract: In a method for forming a semiconductor device, a gate electrode is formed over a semiconductor body (e.g., bulk silicon substrate or SOI layer). The gate electrode is electrically insulated from the semiconductor body. A first sidewall spacer is formed along a sidewall of the gate electrode. A sacrificial sidewall spacer is formed adjacent the first sidewall spacer. The sacrificial sidewall spacer and the first sidewall spacer overlying the semiconductor body. A planarization layer is formed over the semiconductor body such that a portion of the planarization layer is adjacent the sacrificial sidewall spacer. The sacrificial sidewall spacer can then be removed and a recess etched in the semiconductor body. The recess is substantially aligned between the first sidewall spacer and the portion of the planarization layer. A semiconductor material (e.g., SiGe or SiC) can then be formed in the recess.

Abstract: A method for fabricating an electronic device, comprising wafer bonding a first semiconductor material to a III-nitride semiconductor, at a temperature below 550° C., to form a device quality heterojunction between the first semiconductor material and the III-nitride semiconductor, wherein the first semiconductor material is different from the III-nitride semiconductor and is selected for superior properties, or preferred integration or fabrication characteristics in the injector region as compared to the III-nitride semiconductor.

Abstract: A fin structure for a fin field effect transistor (FinFET) device is provided. The device includes a substrate, a first semiconductor material disposed on the substrate, a shallow trench isolation (STI) region disposed over the substrate and formed on opposing sides of the first semiconductor material, and a second semiconductor material forming a first fin and a second fin disposed on the STI region, the first fin spaced apart from the second fin by a width of the first semiconductor material. The fin structure may be used to generate the FinFET device by forming a gate layer formed over the first fin, a top surface of the first semiconductor material disposed between the first and second fins, and the second fin.

Abstract: An embodiment of the invention reduces the external resistance of a transistor by utilizing a silicon germanium alloy for the source and drain regions and a nickel silicon germanium self-aligned silicide (i.e., salicide) layer to form the contact surface of the source and drain regions. The interface of the silicon germanium and the nickel silicon germanium silicide has a lower specific contact resistivity based on a decreased metal-semiconductor work function between the silicon germanium and the silicide and the increased carrier mobility in silicon germanium versus silicon. The silicon germanium may be doped to further tune its electrical properties. A reduction of the external resistance of a transistor equates to increased transistor performance both in switching speed and power consumption.

Abstract: This invention relates to a semiconductor device and a manufacturing method thereof for reducing stacking faults caused by high content of Ge in an embedded SiGe structure. The semiconductor device comprises a Si substrate with a recess formed therein. A first SiGe layer having a Ge content gradually increased from bottom to top is formed on the recess bottom, a SiGe seed layer is formed on sidewalls of the recess and a second SiGe layer having a constant content of Ge is formed on the first SiGe layer. The thickness of the first SiGe layer is less than the depth of the recess. The Ge content in the SiGe seed layer is less than the Ge content in the second SiGe layer and the Ge content at the upper surface of the first SiGe layer is less than or equal to the Ge content in the second SiGe layer.

Abstract: Cell electrodes are provided respectively for cell structures on a semiconductor substrate. The cell electrodes are divided into groups each including two or more cell electrodes. Conductive members are respectively electrically connected to the groups. The conductive members have a used portion and an unused portion. The used portion has two or more conductive members electrically connected to each other. The unused portion has at least one of the conductive members and is electrically insulated from the used portion.

Abstract: A semiconductor device having epitaxial structures includes a gate structure positioned on a substrate, epitaxial structures formed in the substrate at two sides of the gate structure, and an undoped cap layer formed on the epitaxial structures. The epitaxial structures include a dopant, a first semiconductor material having a first lattice constant, and a second semiconductor material having a second lattice constant, and the second lattice constant is larger than the first lattice constant. The undoped cap layer also includes the first semiconductor material and the second semiconductor material. The second semiconductor material in the epitaxial structures includes a first concentration, the second semiconductor material in the undoped cap layer includes at least a first concentration, and the second concentration is lower than the first concentration.

Abstract: A structure and method for fabricating a light emitting diode and a light detecting diode on a silicon-on-insulator (SOI) wafer is provided. Specifically, the structure and method involves forming a light emitting diode and light detecting diode on the SOI wafer's backside and utilizing a deep trench formed in the wafer as an alignment marker. The alignment marker can be detected by x-ray diffraction, reflectivity, or diffraction grating techniques. Moreover, the alignment marker can be utilized to pattern openings and perform ion implantation to create p-n junctions for the light emitting diode and light detecting diode. By utilizing the SOI wafer's backside, the structure and method increases the number of light emitting diodes and light detecting diodes that can be formed on a SOI wafer, enables an increase in overall device density for an integrated circuit, and reduces attenuation of light signals being emitted and detected by the diodes.

Abstract: A semiconductor device and the methods of forming the same are provided. The semiconductor device includes a low energy band-gap layer comprising a semiconductor material; a gate dielectric on the low energy band-gap layer; a gate electrode over the gate dielectric; a first source/drain region adjacent the gate dielectric, wherein the first source/drain region is of a first conductivity type; and a second source/drain region adjacent the gate dielectric. The second source/drain region is of a second conductivity type opposite the first conductivity type. The low energy band-gap layer is located between the first and the second source/drain regions.

Abstract: A semiconductor-on-insulator structure and a method of forming the silicon-on-insulator structure including an integrated graphene layer are disclosed. In an embodiment, the method comprises processing a silicon material to form a buried oxide layer within the silicon material, a silicon substrate below the buried oxide, and a silicon-on-insulator layer on the buried oxide. A graphene layer is transferred onto the silicon-on-insulator layer. Source and drain regions are formed in the silicon-on-insulator layer, and a gate is formed above the graphene. In one embodiment, the processing includes growing a respective oxide layer on each of first and second silicon sections, and joining these silicon sections together via the oxide layers to form the silicon material. The processing, in an embodiment, further includes removing a portion of the first silicon section, leaving a residual silicon layer on the bonded oxide, and the graphene layer is positioned on this residual silicon layer.

Abstract: Methods involve using a memory array having memory cells comprising a diode and an antifuse, in which the antifuse is made smaller and programmed at lower voltage by using an antifuse material having a higher dielectric constant and a higher acceleration factor than those of silicon dioxide, and in which the diode is made of a material having a lower band gap than that of silicon. Such memory arrays can be made to have long operating lifetimes by using the high acceleration factor and lower band gap materials. Antifuse materials having dielectric constants between 5 and 27, for example, hafnium silicon oxynitride or hafnium silicon oxide, are particularly effective. Diode materials with band gaps lower than that of silicon, such as germanium or a silicon-germanium alloy, are particularly effective.

Abstract: A single crystal germanium-on-silicon structure includes a single crystal silicon substrate. A single crystal layer of gadolinium oxide is epitaxially grown on the substrate. The gadolinium oxide has a cubic crystal structure and a lattice spacing approximately equal to the lattice spacing or a multiple of the single crystal silicon. A single crystal layer of lanthanum oxide is epitaxially grown on the gadolinium oxide with a thickness of approximately 12 nm or less. The lanthanum oxide has a lattice spacing approximately equal to the lattice spacing or a multiple of single crystal germanium and a cubic crystal structure approximately similar to the cubic crystal structure of the gadolinium oxide. A single crystal layer of germanium with a (111) crystal orientation is epitaxially grown on the layer of lanthanum oxide.

Abstract: A field effect transistor according to an embodiment includes: a semiconductor layer; a source region and a drain region formed at a distance from each other in the semiconductor layer; a gate insulating film formed on a portion of the semiconductor layer, the portion being located between the source region and the drain region; a gate electrode formed on the gate insulating film; and a gate sidewall formed on at least one of side faces of the gate electrode, the side faces being located on a side of the source region and on a side of the drain region, the gate sidewall being made of a high dielectric material. The source region and the drain region are separately-placed from the corresponding side faces of the gate electrode.

Abstract: Epitaxially grown extension regions are disclosed for scaled CMOS devices. Semiconductor devices are provided that comprise a field effect transistor (FET) structure having a gate stack on a silicon substrate, wherein the field effect transistor structure comprises at least a channel layer formed below the gate stack. One or more etched extension regions containing an epitaxially grown dopant are provided in the channel layer.

Abstract: Disclosed are a method which improves the performance of a semiconductor element, and a semiconductor element with improved performance. The method for forming a semiconductor element structure includes a heterojunction forming step in which a heterojunction is formed between a strained semiconductor layer (21) in which a strained state is maintained, and relaxed semiconductor layers (23, 25). The heterojunction is formed by performing ion implantation from the surface of a substrate (50) which has a strained semiconductor layer (20) partially covered with a covering layer (30) on an insulating oxide film (40), and altering the strained semiconductor layer (20) where there is no shielding from the covering layer (30) to relaxed semiconductor layers (23, 25) by relaxing the strained state of the strained semiconductor layer (20), while maintaining the strained state of the strained semiconductor layer (21) where there is shielding from the covering layer (30).

Abstract: Embodiments of semiconductor devices and methods for fabricating the semiconductor devices are provided. The method includes forming a cavity in a semiconductor region laterally adjacent to a gate electrode structure of a transistor. The gate electrode structure is disposed on a channel region of a first silicon-germanium alloy. A strain-inducing silicon-germanium alloy is formed in the cavity and in contact with the first silicon-germanium alloy. The strain-inducing silicon-germanium alloy includes carbon and has a composition different from the first silicon-germanium alloy.

Abstract: Various source/drain stressors that can enhance carrier mobility, and methods for manufacturing the same, are disclosed. An exemplary source/drain stressor includes a seed layer of a first material disposed over a substrate of a second material, the first material being different than the second material; a relaxed epitaxial layer disposed over the seed layer; and an epitaxial layer disposed over the relaxed epitaxial layer.

Abstract: Disclosed are methods for manufacturing semiconductor devices and the devices thus obtained. In one embodiment, the method comprises obtaining a semiconductor substrate comprising a germanium region doped with n-type dopants at a first doping level and forming an interfacial silicon layer overlying the germanium region, where the interfacial silicon layer is doped with n-type dopants at a second doping level and has a thickness higher than a critical thickness of silicon on germanium, such that the interfacial layer is at least partially relaxed. The method further includes forming over the interfacial silicon layer a layer of material having an electrical resistivity smaller than 1×10?2 ?cm, thereby forming an electrical contact between the germanium region and the layer of material, wherein the electrical contact has a specific contact resistivity below 10?4 ?cm2.

Abstract: The invention provides a graphene device structure and a method for manufacturing the same, the device structure comprising a graphene layer; a gate region in contact with the graphene layer; semiconductor doped regions formed in the two opposite sides of the gate region and in contact with the graphene layer, wherein the semiconductor doped regions are isolated from the gate region; a contact formed on the gate region and contacts formed on the semiconductor doped regions. The on-off ratio of the graphene device is increased through the semiconductor doped regions without increasing the band gap of the graphene material, i.e., without affecting the mobility of the material or the speed of the device, thereby increasing the applicability of the graphene material in CMOS devices.

Abstract: A power transistor includes a first terminal, a second terminal and a control terminal. A support layer is formed of a first material having a first bandgap. An active region is formed of a second material having a second bandgap wider than the first bandgap, and is disposed on the support layer. The active region is arranged to form part of a current path between the first and second terminal in a forward mode of operation. The active region includes at least one pn-junction.

Abstract: A silicon wafer contains: a silicon substrate; a first epitaxial layer on the silicon wafer, wherein the absolute value of the difference between donor and acceptor concentrations is ?1×1018 atoms/cm3; a second epitaxial layer above the first epitaxial layer, whose conductivity type is the same as the first epitaxial layer, wherein the absolute value of the difference between donor and acceptor concentrations is ?5×1017 atoms/cm3; wherein, by doping a lattice constant adjusting material into the first epitaxial layer, the variation amount ((a1-aSi)/aSi) of the lattice constant of the first epitaxial layer (a1) relative to the lattice constant of the silicon single crystal (aSi) as well as the variation amount ((a2-aSi)/aSi) of the lattice constant of the second epitaxial layer (a2) relative to the lattice constant of the silicon single crystal (aSi) are controlled to less than the critical lattice mismatch.

Abstract: A field effect transistor includes a partial SiGe channel, i.e., a channel including a SiGe channel portion, located underneath a gate electrode and a Si channel portion located underneath an edge of the gate electrode near the drain region. The SiGe channel portion can be located directly underneath a gate dielectric, or can be located underneath a Si channel layer located directly underneath a gate dielectric. The Si channel portion is located at the same depth as the SiGe channel portion, and contacts the drain region of the transistor. By providing a Si channel portion near the drain region, the GIDL current of the transistor is maintained at a level on par with the GIDL current of a transistor having a silicon channel only during an off state.

Abstract: The semiconductor wafer includes: a base wafer; and an inhibition layer that is disposed on the base wafer as one piece or to be separate portions from each other, and inhibits growth of a crystal of a compound semiconductor, where the inhibition layer has a plurality of first opening regions that have a plurality of openings penetrating the inhibition layer and leading to the base wafer, each of the plurality of first opening regions includes therein a plurality of first openings disposed in the same arrangement, some of the plurality of first openings are first element forming openings each provided with a first compound semiconductor on which an electronic element is to be formed, and the other of the plurality of first openings are first dummy openings in which no electronic element is to be formed.

Abstract: The invention relates to a method for forming a semiconductor heterostructure by providing a substrate with a first in-plane lattice parameter a1, providing a buffer layer with a second in-plane lattice parameter a2 and providing a top layer over the buffer layer. In order to improve the surface roughness of the semiconductor heterostructure, an additional layer is provided in between the buffer layer and the top layer, wherein the additional layer has a third in-plane lattice parameter a3 which is in between the first and second lattice parameters.

Abstract: Methods (and semiconductor substrates produced therefrom) of fabricating (n?1) SDOI substrates using n wafers is described. A donor substrate (e.g., silicon) includes a buffer layer (e.g., SiGe) and a plurality of multi-layer stacks formed thereon having alternating stress (e.g., relaxed SiGe) and strain (e.g., silicon) layers. An insulator is disposed adjacent an outermost strained silicon layer. The outermost strained silicon layer and underlying relaxed SiGe layer is transferred to a handle substrate by conventional or known bonding and separation methods. The handle substrate is processed to remove the relaxed SiGe layer thereby producing an SDOI substrate for further use. The remaining donor substrate is processed to remove one or more layers to expose another strained silicon layer. Various processing steps are repeated to produce another SDOI substrate as well as a remaining donor substrate, and the steps may be repeated to produce n?1 SDOI substrates.

Abstract: A semiconductor device includes a substrate including a first region and a second region each having an n-type region and a p-type region, wherein the n-type region in the first region includes a silicon channel, the p-type region in the first region includes a silicon germanium channel, and the n-type region and the p-type region in the second region respectively include a silicon channel. A first gate insulating pattern formed of a thermal oxide layer is disposed on the substrate of the n-type and p-type regions in the second region.

Abstract: A substrate material including a Si-containing substrate and an insulating region that is resistant to Ge diffusion present atop the Si-containing substrate. The substrate material further includes a substantially relaxed SiGe alloy layer present atop the insulating region, wherein the substantially relaxed SiGe alloy layer has a planar defect density from about 5000 defects/cm?2 or less. The substrate material may be employed in a heterostructure, in which a strained Si layer is present atop the substantially relaxed SiGe alloy layer of the substrate material.

Abstract: In a thin film transistor, a semiconductor layer containing Si and Ge is applied, a Ge concentration of this semiconductor layer is high at the side of the insulating substrate, and crystalline orientation of the semiconductor layer indicates a random orientation in a region of 20 nm from the side of the insulating substrate, and indicates a (111), (110) or (100) preferential orientation at the film surface side of the semiconductor layer.

Abstract: There is provided a method of producing a semiconductor wafer by thermally processing a base water having a portion to be thermally processed that is to be thermally processed. The method comprises a step of providing, on the base wafer, a portion to be heated that generates heat through absorption of an electromagnetic wave and selectively heats the portion to be thermally processed, a step of applying an electromagnetic wave to the base wafer, and a step of lowering the lattice defect density of the portion to he thermally processed, by means of the heat generated by the portion to be heated through the absorption of the electromagnetic wave.

Abstract: A semiconductor device according to an embodiment includes: a semiconductor substrate; a gate electrode formed on the semiconductor substrate via a gate insulating film; a channel region formed in a region of the semiconductor substrate below the gate electrode; an epitaxial crystal layer containing a conductive impurity, which is formed sandwiching the channel region and has a function as a source region and a drain region, and formed on a recess in the semiconductor substrate; and a growth suppressing portion formed on the recess in the semiconductor substrate, and configured to suppress an epitaxial growth of a crystal in the epitaxial layer from the semiconductor substrate.

Abstract: A device forming thin film for forming a semiconductor device; an inhibition portion that surrounds the device forming thin film and inhibits growth of a precursor of the device forming thin film into a crystal; a sacrificial growth portion that is formed by causing the precursor to sacrificially grow into a crystal, and is positioned around the device forming thin film separated by the inhibition portion; and a protection film that covers a top portion of the sacrificial growth portion and exposes a top portion of the device forming thin film are included. The protection film may be made of polyimide.

Abstract: Growth of multilayer films is carried out in a manner which allows close control of the strain in the grown layers and complete release of the grown films to allow mounting of the released multilayer structures on selected substrates. A layer of material, such as silicon-germanium, is grown onto a template layer, such as silicon, of a substrate having a sacrificial layer on which the template layer is formed. The grown layer has a lattice mismatch with the template layer so that it is strained as deposited. A top layer of crystalline material, such as silicon, is grown on the alloy layer to form a multilayer structure with the grown layer and the template layer. The sacrificial layer is preferentially etched away to release the multilayer structure from the sacrificial layer, relaxing the grown layer and straining the crystalline layers interfaced with it.

Abstract: A PMOS field effect transistor includes a substrate, a first nitride layer, a mesa structure, two gate oxide films, a gate stack layer and a second nitride layer. The substrate has a oxide layer and a first doping area. The first nitride layer is located on the oxide layer. The mesa structure includes a first strained Si—Ge layer, an epitaxial Si layer and a second strained Si—Ge layer. The first strained Si—Ge layer is located on the oxide layer and the first nitride layer. The epitaxial Si layer is located on the first strained Si—Ge layer. The second strained Si—Ge layer is located on the epitaxial Si layer. In the surface layer of the second strained Si—Ge layer, there is a second doping area. The two gate oxide films are located at two sides of the mesa structure.