Abstract: A semiconductor component is disclosed herein comprising a drift zone and a drift control zone. The drift control zone is arranged adjacent to the drift zone and is dielectrically insulated from the drift zone by a dielectric layer. The drift control zone includes at least one first semiconductor layer and one second semiconductor layer. The first semiconductor layer has a higher charge carrier mobility than the second semiconductor layer.

Abstract: A semiconductor device includes a gate electrode formed on a silicon substrate in correspondence to a channel region via a gate insulation film, and source and drain regions of p-type formed in the silicon substrate at respective outer sides of sidewall insulation films on the gate electrode, a pair of SiGe mixed crystal regions formed in the silicon substrate at respective outer sides of the sidewall insulation films epitaxially to the silicon substrate so as to be enclosed respectively by the source and drain regions, each of the SiGe mixed crystal regions being grown to a level above a level of a gate insulation film interface between the gate insulation film and the silicon substrate, wherein there is provided a compressive stress film at respective top surfaces of the SiGe mixed crystal regions.

Abstract: High frequency performance of (e.g., silicon) bipolar devices (40, 100, 100?) is improved by reducing the capacitive coupling (Cbc) between the extrinsic base contact (46) and the collector (44, 44?, 44?). A dielectric ledge (453, 453?) is created during fabrication to separate the extrinsic base contract (46) from the collector (44, 44?, 44?) periphery (441). The dielectric ledge (453, 453?) underlies the transition region (461) where the extrinsic base contact (46) is coupled to the intrinsic base. (472) During device fabrication, a multi layer dielectric stack (45) is formed adjacent the intrinsic base (472) that allows the simultaneous creation of an undercut region (457, 457?) in which the intrinsic base (472) to extrinsic base contact (46) transition region (461) can be formed.

Abstract: The present invention provides a semiconductor device and a method of forming thereof, in which a uniaxial strain is produced in the device channel of the semiconductor device. The uniaxial strain may be in tension or in compression and is in a direction parallel to the device channel. The uniaxial strain can be produced in a biaxially strained substrate surface by strain inducing liners, strain inducing wells or a combination thereof. The uniaxial strain may be produced in a relaxed substrate by the combination of strain inducing wells and a strain inducing liner. The present invention also provides a means for increasing biaxial strain with strain inducing isolation regions. The present invention further provides CMOS devices in which the device regions of the CMOS substrate may be independently processed to provide uniaxially strained semiconducting surfaces in compression or tension.

Abstract: LED devices and methods for making such devices are provided. One such method may include forming epitaxially a substantially single crystal SiC layer on a substantially single crystal Si wafer, forming epitaxially a substantially single crystal diamond layer on the SiC layer, doping the diamond layer to form a conductive diamond layer, removing the Si wafer to expose the SiC layer opposite to the conductive diamond layer, forming epitaxially a plurality of semiconductor layers on the SiC layer such that at least one of the semiconductive layers contacts the SiC layer, and coupling an n-type electrode to at least one of the semiconductor layers such that the plurality of semiconductor layers is functionally located between the conductive diamond layer and the n-type electrode.

Abstract: Semiconductor devices and methods for making such devices are provided. One such method may include forming an epitaxial layer of single crystal SiC on a single crystal Si growth substrate, forming an epitaxial diamond layer on the layer of SiC, forming a Si layer on the diamond layer, bonding a SiO2 surface of a Si carrier substrate to the Si layer, and removing the Si growth substrate to expose the SiC layer. In yet another aspect, a semiconductor layer may be deposited onto the SiC layer. The semiconductor layer may further be deposited epitaxially.

Abstract: Methods for forming embedded epitaxial layers containing silicon and carbon are disclosed. Specific embodiments pertain to the formation embedded epitaxial layers containing silicon and carbon on silicon wafers. In specific embodiments an epitaxial layer of silicon and carbon is non-selectively formed on a substrate or silicon wafer, portions of this layer are removed to expose the underlying substrate or silicon wafer, and an epitaxial layer containing silicon is formed on the exposed substrate or silicon wafers. In specific embodiments, gates are formed on the resulting silicon-containing epitaxial layers.

Abstract: Embodiments of the invention provide a method of forming embedded silicon germanium (eSiGe) in source and drain regions of a p-type field-effect-transistor (pFET) through a disposable spacer process; depositing a gap-filling layer directly on the eSiGe in the source and drain regions in a first process; depositing a layer of offset spacer material on top of the gap-filling layer in a second process different from the first process; etching the offset spacer material and the gap-filling layer, thus forming a set of offset spacers and exposing the eSiGe in the source and drain regions of the pFET; and finishing formation of the pFET.

Abstract: A method of manufacturing a silicon carbide semiconductor device includes forming a trench for a MOS gate in an SiC substrate by dry etching. Thereafter, the substrate with the trench is heat treated. The heat treatment includes heating the substrate in an Ar gas atmosphere or in a mixed gas atmosphere containing SiH4 and Ar at a temperature between 1600° C. and 1800° C., and thereafter in a hydrogen gas atmosphere at a temperature between 1400° C. and 1500° C. The present manufacturing method smoothens the trench inner surface and rounds the corners in the trench to prevent the electric field from localizing thereto.

Abstract: A method of fabricating a semiconductor device is disclosed that is able to suppress a short channel effect and improve carrier mobility. In the method, trenches are formed in a silicon substrate corresponding to a source region and a drain region. When epitaxially growing p-type semiconductor mixed crystal layers to fill up the trenches, the surfaces of the trenches are demarcated by facets, and extended portions of the semiconductor mixed crystal layers are formed between bottom surfaces of second side wall insulating films and a surface of the silicon substrate, and extended portion are in contact with a source extension region and a drain extension region.

Abstract: A MOS transistor having a highly stressed channel region and a method for forming the same are provided. The method includes forming a first semiconductor plate over a semiconductor substrate, forming a second semiconductor plate on the first semiconductor plate wherein the first semiconductor plate has a substantially greater lattice constant than the second semiconductor plate, and forming a gate stack over the first and the second semiconductor plates. The first and the second semiconductor plates include extensions extending substantially beyond side edges of the gate stack. The method further includes forming a silicon-containing layer on the semiconductor substrate, preferably spaced apart from the first and the second semiconductor plates, forming a spacer, a LDD region and a source/drain region, and forming a silicide region and a contact etch stop layer. A high stress is developed in the channel region. Current crowding effects are reduced due to the raised silicide region.

Abstract: Methods and apparatus provide for a glass or glass ceramic substrate, including: a bulk layer; an enhanced positive ion concentration layer; and a reduced positive ion concentration layer, wherein the enhanced positive ion concentration layer contains substantially all modifier positive ions from the reduced positive ion concentration layer as a result of migration, the substrate does not include any further material thereon.

Abstract: A semiconductor workpiece including a substrate, a relaxed buffer layer including a graded portion formed on the substrate, and at least one strained transitional layer within the graded portion of the relaxed buffer layer and method of manufacturing the same.

Abstract: A method for producing a microelectronic device comprising a plurality of Si1-yGey based semi-conductor zones (wherein 0<y?1) that have different respective Germanium contents.

Abstract: A first aspect of the invention provides a method of selectively forming an epitaxial layer on a substrate. The method includes heating the substrate to a temperature of less than about 800° C. and employing both silane and dichlorosilane as silicon sources during epitaxial film formation. Numerous other aspects are provided.

Abstract: A method of fabricating a semiconductor device is disclosed that is able to suppress a short channel effect and improve carrier mobility. In the method, trenches are formed in a silicon substrate corresponding to a source region and a drain region. When epitaxially growing p-type semiconductor mixed crystal layers to fill up the trenches, the surfaces of the trenches are demarcated by facets, and extended portions of the semiconductor mixed crystal layers are formed between bottom surfaces of second side wall insulating films and a surface of the silicon substrate, and extended portion are in contact with a source extension region and a drain extension region.

Abstract: A method for forming a semiconductor device includes forming a recess in a source region and a recess in a drain region of the semiconductor device. The method further includes forming a first semiconductor material layer in the recess in the source region and a second semiconductor material layer in the recess in the drain region, wherein each of the first semiconductor material layer and the second semiconductor material layer are formed using a stressor material having a first ratio of an atomic concentration of a first element and an atomic concentration of a second element, wherein the first element is silicon and a first level of concentration of a doping material. The method further includes forming additional semiconductor material layers overlying the first semiconductor material layer and the second semiconductor material layer that have a different ratio of the atomic concentration of the first element and the second element.

Abstract: Provided is a strained SOI structure and a method of manufacturing the strained SOI structure. The strained SOI structure includes an insulating substrate, a SiO2 layer formed on the insulating substrate, and a strained silicon layer formed on the SiO2 layer.

Abstract: A method for making an NMOS transistor on a semiconductor substrate includes reducing the thickness of the PMD layer to expose the polysilicon gate electrode of the NMOS transistor and the polysilicon gate electrode of the PMOS transistor, and then removing the gate electrode of the NMOS transistor. The method also includes depositing a NMOS-metal layer over the semiconductor substrate, depositing a fill-metal layer over the NMOS-metal layer, and then reducing the thickness of the NMOS metal layer and the fill metal layer to expose the gate electrodes of the NMOS transistor and the PMOS transistor.

Abstract: The present invention provides for a low-temperature method to crystallize a silicon-germanium film. Metal-induced crystallization of a deposited silicon film can serve to reduce the temperature required to crystallize the film. Increasing germanium content in a silicon-germanium alloy further decreases crystallization temperature. By using metal-induced crystallization to crystallize a deposited silicon-germanium film, temperature can be reduced substantially. In preferred embodiments, for example in a monolithic three dimensional array of stacked memory levels, reduced temperature allows the use of aluminum metallization. In some embodiments, use of metal-induced crystallization in a vertically oriented silicon-germanium diode having conductive contacts at the top and bottom end is be particularly advantageous, as increased solubility of the metal catalyst in the contact material will reduce the risk of metal contamination of the diode.

Abstract: A method for forming an etch-stop layer and a resulting structure fabricated therefrom. The etch-stop layer is a silicon-germanium layer having a ratio of silicon to germanium of about 50:1 or less, a boron layer formed within the silicon-germanium layer where the boron layer has a full-width half-maximum (FWHM) thickness value of less than 50 nanometers, and a carbon layer formed within the silicon-germanium layer where the carbon layer has an FWHM thickness value of less than 50 nanometers. A ratio of boron to carbon in the etch-stop layer is in a range of about 0.5 to 1.5.

Abstract: A CMOS image sensor includes a substrate including silicon, a silicon germanium (SiGe) epitaxial layer formed over the substrate, the SiGe epitaxial layer formed through epitaxial growth and doped with a predetermined concentration level of impurities, an undoped silicon epitaxial layer formed over the SiGe epitaxial layer by epitaxial growth, and a photodiode region formed from a top surface of the undoped silicon epitaxial layer to a predetermined depth in the SiGe epitaxial layer.

Abstract: A semiconductor structure includes a first silicon-containing layer comprising an element selected from the group consisting essentially of carbon and germanium wherein the silicon-containing layer has a first atomic percentage of the element to the element and silicon, a second silicon-containing layer comprising the element over the first silicon-containing layer, and a silicide layer on the second silicon-containing layer. The element in the second silicon-containing layer has a second atomic percentage of the element to the element and silicon, wherein the second atomic percentage is substantially lower than the first atomic percentage.

Abstract: A substantially all diamond transistor with an electrically insulating substrate, an electrically conductive diamond layer on the substrate, and a source and a drain contact on the electrically conductive diamond layer. An electrically insulating diamond layer is in contact with the electrically conductive diamond layer, and a gate contact is on the electrically insulating diamond layer. The diamond layers may be homoepitaxial, polycrystalline, nanocrystalline or ultrananocrystalline in various combinations. A method of making a substantially all diamond self-aligned gate transistor is disclosed in which seeding and patterning can be avoided or minimized, if desired.

Abstract: A non-volatile memory is provided. A substrate having a plurality of trenches and a plurality of select gates is provided. The trenches are arranged in parallel and extend in a first direction. Each of the select gates is disposed on the substrate between two adjacent trenches respectively. A plurality of select gate dielectric layers are disposed between the select gates and the substrate. A plurality of composite layers are disposed over the surface of the trenches and each composite layer has a charge trapping layer. A plurality of word lines are arranged in parallel in a second direction, wherein each of the word lines fills the trenches between adjacent select gates and is disposed over the composite layers.

Abstract: A flash memory device of SONOS structure and a method for fabricating the same, and programming and erasing operation methods, to improve reliability such as endurance and retention, are disclosed, which includes a first conductive type semiconductor substrate; an ONO layer on the semiconductor substrate; a first control gate on the ONO layer; second and third control gates on the ONO layer at both sides of the first control gate; and source and drain regions in the surface of the semiconductor substrate at both sides of the second and third control gates.

Abstract: A method of controlling strain in a single-crystal, epitaxial oxide film, includes preparing a silicon substrate; forming a silicon alloy layer taken from the group of silicon alloy layer consisting of Si1-xGex and Si1-yCy on the silicon substrate; adjusting the lattice constant of the silicon alloy layer by selecting the alloy material content to adjust and to select a type of strain for the silicon alloy layer; depositing a single-crystal, epitaxial oxide film, by atomic layer deposition, taken from the group of oxide films consisting of perovskite manganite materials, single crystal rare-earth oxides and perovskite oxides, not containing manganese; and rare earth binary and ternary oxides, on the silicon alloy layer; and completing a desired device.

Abstract: The invention includes non-volatile memory and logic devices associated with crystalline Si/Ge. The devices can include TFT constructions. The non-volatile devices include a floating gate or floating plate over the Si/Ge, and a pair of source/drain regions. The source/drain regions can extend into the Si/Ge. The memory or logic devices further include an insulative material over the floating gate or plate, and a control gate separated from the floating gate or plate by the insulative material. The crystalline Si/Ge can have a relaxed crystalline lattice, and a crystalline layer having a strained crystalline lattice can be formed between the relaxed crystalline lattice and the floating gate or plate. The devices can be fabricated over any of a variety of substrates. The floating plate option can provide lower programming voltage and orders of magnitude superior endurance compared to other options.

Abstract: A semiconductor device having small electrical contacts to impurity doped regions and a method for fabrication of such a device are provided. In accordance with one embodiment of the invention the semiconductor device comprises a semiconductor substrate having a doped region formed therein. The doped region has a nucleating layer comprising nickel on its surface, and a nanowire structure comprising silicon and carbon electrically contacts the nucleating layer.

Abstract: A method for forming a semiconductor device is provided. The method includes providing a semiconductor substrate, forming a gate dielectric over the semiconductor substrate, forming a gate electrode on the gate dielectric, forming a stressor in the semiconductor substrate adjacent an edge of the gate electrode, and implanting an impurity after the step of forming the stressor. The impurity is preferably selected from the group consisting essentially of group IV elements, inert elements, and combinations thereof.

Abstract: A method for making a SOI wafer with a strained silicon layer for increased electron and hole mobility is achieved. The method forms a porous silicon layer on a seed wafer. A H2 anneal is used to form a smooth surface on the porous silicon. A strain free (relaxed) epitaxial SixGe1-x layer is deposited and a bonding layer is formed. The seed wafer is then bonded to a handle wafer having an insulator on the surface. A spray etch is used to etch the porous Si layer resulting in a SOI handle wafer having portions of the porous Si layer on the relaxed SixGe1-x. The handle wafer is then annealed in H2 to convert the porous Si to a smooth strained Si layer on the relaxed SiGe layer of the SOI wafer.

Abstract: The disclosure relates a method for producing a microelectronic device including a plurality of based Si1-yGey semi-conductor zones (where 0<y?1) have different respective Germanium contents, comprising the steps of: a) formation on a plurality of Si based semi-conductor zones with different thicknesses resting on a substrate, of a Si1-yGey based semi-conductor layer (where 0<x<1 and x<y), b) oxidation of the Si1-yGey based semi-conductor layer.

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: An integrated circuit (IC) utilizes a strained layer. The substrate can utilize trenches in a base layer to induce stress in a layer. The trenches define pillars on a back side of a bulk substrate or base layer of a semiconductor-on-insulator (SOI) wafer.

Abstract: A MOSgated trench device has a reduced on resistance by forming a less than about a 13 nm thick strained SiGe layer on the silicon surface of the trenches and forming a thin (30 nm or less) layer of epitaxially deposited silicon on the SiGe layer which epi layer is converted to a gate oxide layer. The conduction channel formed by the SiGe layer is permanently strained to increase its mobility particularly hole mobility.

Abstract: Various embodiments of the invention relate to a PMOS device having a transistor channel of silicon germanium material on a substrate, a gate dielectric having a dielectric constant greater than that of silicon dioxide on the channel, a gate electrode conductor material having a work function in a range between a valence energy band edge and a conductor energy band edge for silicon on the gate dielectric, and a gate electrode semiconductor material on the gate electrode conductor material.

Abstract: Methods are provided for fabricating a stressed MOS device. The method comprises the steps of forming a plurality of parallel MOS transistors in and on a semiconductor substrate. The parallel MOS transistors having a common source region, a common drain region, and a common gate electrode. A first trench is etched into the substrate in the common source region and a second trench is etched into the substrate in the common drain region. A stress inducing semiconductor material that has a crystal lattice mismatched with the semiconductor substrate is selectively grown in the first and second trenches. The growth of the stress inducing material creates both compressive longitudinal and tensile transverse stresses in the MOS device channel that enhance the drive current of P-channel MOS transistors. The decrease in drive current of N-channel MOS transistors caused by the compressive stress component is offset by the tensile stress component.

Abstract: A method and apparatus is presented that provides performance enhancement in a semiconductor device. In one embodiment, a first current region (64, 76, 23), a channel region and a second current region (75, 33, 66) are adjacent each other. The second current region (75, 33, 66) has a content of a first element of an alloy greater than a content of the first element in the first current region (64, 76, 23), wherein the second current region (75, 33, 66) has a content of the first element greater than a content of the first element in the channel region, the alloy further comprises a second element, the first element has a first valence number, and the second element has a second valence number. Furthermore, the sum of the first valence number and the second valence number is eight.

Abstract: A method of fabricating an integrated circuit on a silicon carbide substrate is disclosed that eliminates wire bonding that can otherwise cause undesired inductance. The method includes fabricating a semiconductor device in epitaxial layers on a surface of a silicon carbide substrate and with at least one metal contact for the device on the uppermost surface of the epitaxial layer. The opposite surface of the substrate is then ground and polished until it is substantially transparent. The method then includes masking the polished surface of the silicon carbide substrate to define a predetermined location for at least one via that is opposite the device metal contact on the uppermost surface of the epitaxial layer and etching the desired via in steps. The first etching step etches through the silicon carbide substrate at the desired masked location until the etch reaches the epitaxial layer. The second etching step etches through the epitaxial layer to the device contacts.

Abstract: The vertical diffusion of dopants from the gate and the bulk material into the channel region, and the lateral diffusion of dopants from the source and drain regions into the channel region resulting from thermal cycling during the fabrication of a MOS transistor is minimized by forming the source and drain regions in a layer of composite material that includes silicon, germanium, and carbon.

Abstract: A structure and method of fabricating a high-mobility semiconductor layer structure and field-effect transistor (MODFET) that includes a high-mobility conducting channel, while at the same time, maintaining counter doping to control deleterious short-channel effects. The MODFET design includes a high-mobility conducting channel layer wherein the method allows the counter doping to be formed using a standard technique such as ion implantation, and further allows the high-mobility channel to be in close proximity to the counter doping without degradation of the mobility.

Abstract: A semiconductor device having a gate with a negative slope and a method of manufacturing the same. A poly-SiGe layer with a Ge density profile which decreases linearly from the bottom of the gate toward the top of the gate is formed and a poly-SiGe gate having a negative slope is formed by patterning the poly-SiGe layer. It is possible to form a gate whose bottom is shorter than its top defined by photolithography by taking advantage of the variation of etching characteristics with Ge density when patterning. Accordingly, the gate is compact enough for a short channel device and gate resistance can be reduced.