Abstract: This semiconductor device includes a silicon carbide layer of a first conductivity type having first and second principal surfaces and including an element region and a terminal region surrounding the element region on the first principal surface. The silicon carbide layer includes a first dopant layer of the first conductivity type contacting with the first principal surface and a second dopant layer of the first conductivity type located closer to the second principal surface than the first dopant layer is. The terminal region has, in its surface portion with a predetermined depth under the first principal surface, a terminal structure including respective portions of the first and second dopant layers and a ring region of a second conductivity type running through the first dopant layer to reach the second dopant layer. The dopant concentration of the first dopant layer is twice to five times as high as that of the second dopant layer 22.

Abstract: In one embodiment, the present invention includes a method for forming a logic device, including forming an n-type semiconductor device over a silicon (Si) substrate that includes an indium gallium arsenide (InGaAs)-based stack including a first buffer layer, a second buffer layer formed over the first buffer layer, a first device layer formed over the second buffer layer. Further, the method may include forming a p-type semiconductor device over the Si substrate from the InGaAs-based stack and forming an isolation between the n-type semiconductor device and the p-type semiconductor device. Other embodiments are described and claimed.

Abstract: A method of manufacturing a semiconductor device by using a substrate processing apparatus comprises a reaction chamber configured to process a plurality of substrates stacked at predetermined intervals, wherein a first gas flow from a first gas supply inlet and a second gas flow from a second gas supply inlet are crossed with each other before these gas flows reach the substrates. The method of manufacturing a semiconductor device comprises: loading the plurality of substrates into the reaction chamber; supplying a silicon-containing gas and a chlorine-containing gas from the first gas supply inlet into the reaction chamber, supplying a carbon-containing gas and a reducing gas from the second gas supply inlet into the reaction chamber and supplying a dopant-containing gas into the reaction chamber from the first gas supply inlet or the second gas supply inlet; and unloading the substrates from the reaction chamber.

Abstract: A composite wafer includes a molded wafer and a second wafer. The molded wafer includes a plurality of first components, and the second wafer includes a plurality of second components. The second wafer is combined with the molded wafer to form the composite wafer. At least one of the first components is aligned with at least one of the second components to form a multi-component element. The multi-component element is singulatable from the composite wafer.

Abstract: According to one embodiment, a semiconductor light emitting device includes: first and second semiconductor layers, a light emitting part, and an In-containing layer. The first semiconductor layer is formed on a silicon substrate via a foundation layer. The light emitting part is provided on the first semiconductor layer, and includes barrier layers and a well layer provided between the barrier layers including Ga1?z1Inz1N (0<z1?1). The second semiconductor layer is provided on the light emitting part. The In-containing layer is provided at at least one of first and second positions. The first position is between the first semiconductor layer and the light emitting part. The second position is between the second semiconductor layer and the light emitting part. The In-containing layer includes In with a composition ratio different from the In composition ratio z1 and has a thickness 10 nm to 1000 nm.

Abstract: Methods for wafer-level packaging of microfeature devices and microfeature devices formed using such methods are disclosed herein. A method for packaging microfeature devices in accordance with an embodiment of the invention can include releasably attaching a plurality of first known good microelectronic dies to a carrier substrate in a desired arrangement. In several embodiments, for example, the first dies can be releasably attached to an attachment feature on the carrier substrate. The method can also include attaching one or more second known good microelectronic dies to the individual first dies in a stacked configuration to form a plurality of stacked devices. The method further includes at least partially encapsulating the stacked devices and separating the stacked devices from each other.

Abstract: A silicon oxide film is formed on an epitaxial layer by dry thermal oxidation, an ohmic electrode is formed on a back surface of a SiC substrate, an ohmic junction is formed between the ohmic electrode and the back surface of the SiC substrate by annealing the SiC substrate, the silicon oxide film is removed, and a Schottky electrode is formed on the epitaxial layer. Then, a sintering treatment is performed to form a Schottky junction between the Schottky electrode and the epitaxial layer.

Abstract: A structure and method of fabricating a semiconductor field-effect transistor (MOSFET) such as a strained Si n-MOSFET where dislocation or crystal defects spanning from source to drain is partially occupied by heavy p-type dopants. Preferably, the strained-layer n-MOSFET includes a Si, SiGe or SiGeC multi-layer structure having, in the region between source and drain, impurity atoms that preferentially occupy the dislocation sites so as to prevent shorting of source and drain via dopant diffusion along the dislocation. Advantageously, devices formed as a result of the invention are immune to dislocation-related failures, and therefore are more robust to processing and material variations. The invention thus relaxes the requirement for reducing the threading dislocation density in SiGe buffers, since the devices will be operable despite the presence of a finite number of dislocations.

Abstract: A semiconductor device assembly and method can include a single semiconductor layer or stacked semiconductor layers, for example semiconductor wafers or wafer sections (semiconductor dice). On each semiconductor layer, a diamond layer formed therethrough can aid in the routing and dissipation of heat. The diamond layer can include a first portion on the back of the semiconductor layer, and one or more second portions which extend vertically into the semiconductor layer, for example completely through the semiconductor layer. Thermal contact can then be made to the diamond layer to conduct heat away from the one or more semiconductor layers. A conductive via can be formed through the diamond layers to provide signal routing and heat dissipation capabilities.

Abstract: An elongate device (e.g. a catheter) for interventional MRI has one or more passive LC-circuits (wireless markers) attached to its distal tip portion for position tracking. The LC-circuits comprise an inductor winding (480) and a three-dimensional “trench” capacitor (420-440) and are integrated in a piece of silicon (410). Optical fibres may be included in the device for optical probing of tissue surrounding the distal tip portion.

Abstract: A method and apparatus for the deposition of thin films is described. In embodiments, systems and methods for epitaxial thin film formation are provided, including systems and methods for forming binary compound epitaxial thin films. Methods and systems of embodiments of the invention may be used to form direct bandgap semiconducting binary compound epitaxial thin films, such as, for example, GaN, InN and AlN, and the mixed alloys of these compounds, e.g., (In, Ga)N, (Al, Ga)N, (In, Ga, Al)N. Methods and apparatuses include a multistage deposition process and system which enables rapid repetition of sub-monolayer deposition of thin films.

Abstract: A method for making a cadmium sulfide layer is provided. The method includes a number of steps including providing a substrate and disposing a layer containing cadmium on the substrate followed by sulfurization of the cadmium-containing layer.

Abstract: A nitride semiconductor wafer is planar-processed by grinding a bottom surface of the wafer, etching the bottom surface by, e.g., KOH for removing a bottom process-induced degradation layer, chamfering by a rubber whetstone bonded with 100 wt %-60 wt % #3000-#600 diamond granules and 0 wt %-40 wt % oxide granules, grinding and polishing a top surface of the wafer, etching the top surface for eliminating a top process-induced degradation layer and maintaining a 0.5 ?m-10 ?m thick edge process-induced degradation layer.

Abstract: A method for manufacturing a SiC semiconductor device includes: forming an impurity layer in a SiC layer; and forming an oxide film on the SiC layer. The forming the impurity layer includes: implanting an impurity in the SiC layer; applying a cap layer on the SiC layer; annealing the cap layer to be transformed a carbon layer; annealing the SiC layer to activate the impurity; and removing the carbon layer. The annealing the SiC layer includes: increasing a temperature of the SiC layer from a second temperature to a first temperature within a first time duration; and decreasing the temperature of the SiC layer from the first temperature to the second temperature within a second time duration. The first temperature is equal to or higher than 1800° C., and the second temperature is lower than 1800° C. The first and second time durations are small.

Abstract: A semiconductor processing component has an outer surface portion comprised of silicon carbide, the outer surface portion having a skin impurity level and a bulk impurity level. The skin impurity level is average impurity level from 0 nm to 100 nm of depth into the outer surface portion, the bulk impurity level is measured at a depth of at least 3 microns into the outer surface portion, and the skin impurity level is not greater than 80% of the bulk impurity level.

Abstract: A gate after diamond transistor and method of making comprising the steps of depositing a first dielectric layer on a semiconductor substrate, depositing a diamond particle nucleation layer on the first dielectric layer, growing a diamond thin film layer on the first dielectric layer, defining an opening for the gate in the diamond thin film layer, patterning of the diamond thin film layer for a gate metal to first dielectric layer surface, etching the first dielectric layer, depositing and defining a gate metal, and forming a contact window opening in the diamond thin film layer and the first dielectric layer to the ohmic contact.

Abstract: A production method for a semiconductor device includes providing a semiconductor substrate having semiconductor layer of a first conductivity type formed on a surface thereof; forming a first mask so as to cover a predetermined region of the semiconductor layer; (c) forming a well region of a second conductivity type by implanting impurity ions of the second conductivity type into the semiconductor layer having the first mask formed thereon; reducing the thickness of the first mask by removing a portion of the first mask; forming a second mask covering a portion of the well region by using photolithography; and forming a source region of the first conductivity type by implanting impurity ions of the first conductivity type into the semiconductor layer having the first mask with the reduced thickness and the second mask formed thereon.

Abstract: The present invention relates to a process for fabricating integrated circuit system. More particularly, the process allows for fabrication of highly integrated system-on-a-chip modules through heterogeneous integration of different semiconductor technologies wherein alignment targets on the base semiconductor are used for precise lateral positioning of device structures above.

Abstract: A bipolar junction transistor having an emitter, a base, and a collector includes a stack of one or more layer sets adjacent the collector. Each layer set includes a first material having a first band gap, wherein the first material is highly doped, and a second material having a second band gap narrower than the first band gap, wherein the second material is at most lightly doped.

Abstract: Methods for wafer-level packaging of microfeature devices and microfeature devices formed using such methods are disclosed herein. A method for packaging microfeature devices in accordance with an embodiment of the invention can include releasably attaching a plurality of first known good microelectronic dies to a carrier substrate in a desired arrangement. In several embodiments, for example, the first dies can be releasably attached to an attachment feature on the carrier substrate. The method can also include attaching one or more second known good microelectronic dies to the individual first dies in a stacked configuration to form a plurality of stacked devices. The method further includes at least partially encapsulating the stacked devices and separating the stacked devices from each other.

Abstract: A silicon carbide semiconductor device is disclosed. The silicon carbide semiconductor device includes a substrate; a drift layer having a first conductivity type and located on a first surface of the substrate; and a vertical type semiconductor element. The vertical type semiconductor element includes: an impurity layer having a second conductivity type, and located in a surface portion of the drift layer; and a first conductivity type region located in the drift layer, spaced away from the impurity layer, located closer to the substrate than the impurity layer, and having an impurity concentration higher than the drift layer.

Abstract: A semiconductor substrate that includes a relatively thin monocrystalline useful layer, an intermediate layer transferred from a source substrate, and a relatively thick layer of a support present on one of the useful layer of the intermediate layer. The support is made of a deposited material that has a lower quality than that of one or both of the intermediate and useful layers. A bonding layer may be included on one of the intermediate layer or the useful layer, or both, to facilitate bonding of the layers an a thin layer may be provided between the useful layer and intermediate layer. These final substrates are useful in optic, electronic, or optoelectronic applications.

Abstract: In one aspect the present invention provides a method for manufacturing a silicon carbide semiconductor device. A layer of silicon dioxide is formed on a silicon carbide substrate and nitrogen is incorporated at the silicon dioxide/silicon carbide interface. In one embodiment, nitrogen is incorporated by annealing the semiconductor device in nitric oxide or nitrous oxide. In another embodiment, nitrogen is incorporated by annealing the semiconductor device in ammonia.

Abstract: A substrate includes a first region and a second region. The first region comprises a III-nitride layer, and the second region comprises a first semiconductor layer. A first transistor (such as an n-type transistor) is formed in and on the III-nitride layer, and a second transistor (such as a p-type transistor) is formed in and on the first semiconductor layer. The III-nitride layer may be indium nitride. In the first region, the substrate may include a second semiconductor layer, a graded transition layer over the second semiconductor layer, and a buffer layer over the transition layer, where the III-nitride layer is over the buffer layer. In the second region, the substrate may include the second semiconductor layer and an insulating layer over the second semiconductor layer, where the first semiconductor layer is over the insulating layer.

Abstract: A method of fabricating composite substrates by associating a transfer layer with an intermediate support to form an intermediate substrate of predetermined thickness with the transfer layer having a free surface; providing a sample carrier having a surface and a recess that has a depth that is approximate the same as the predetermined thickness of the intermediate substrate so that the transfer layer free surface is positioned flush with the sample carrier surface; providing a support layer both on the transfer layer free surface and on a portion of the sample carrier surface surrounding the recess; removing the portion of the support layer that extends beyond the intermediate substrate; and detaching the transfer layer and support layer from its intermediate support to form the composite substrate. The support layer is made of a deposited material that has a lower quality than that of the intermediate support.

Abstract: A bonded device structure including a first substrate having a first set of metallic bonding pads, preferably connected to a device or circuit, and having a first non-metallic region adjacent to the metallic bonding pads on the first substrate, a second substrate having a second set of metallic bonding pads aligned with the first set of metallic bonding pads, preferably connected to a device or circuit, and having a second non-metallic region adjacent to the metallic bonding pads on the second substrate, and a contact-bonded interface between the first and second set of metallic bonding pads formed by contact bonding of the first non-metallic region to the second non-metallic region. At least one of the first and second substrates may be elastically deformed.

Abstract: A patterned structure forms a portion of the mold for a diamond molded structure but is separable from the mold by the same processes that release the diamond part. The mold portion may itself be a component in a MEMS or NEMS structure or device or the precursor to such a structure or device. The mold portion may be made from sapphire or silicon carbide. The mold portion may be coated and polished to obtain an optically smooth surface over the diamond mold inside pit. The coating may be formed from one or more of silicon carbide, PTFE, silicon nitride, silicon dioxide, sapphire, a metal, a plastic, and an epoxy.

Abstract: A method for fabrication of a monolithically integrated SOI substrate capacitor has the steps of: forming an insulating trench (14), which reaches down to the insulator (11) and surrounds a region (13?) of the monocrystalline silicon (13) of a SOI structure, doping the monocrystalline silicon region, forming an insulating, which can be nitride, layer region (17?) on a portion of the monocrystalline silicon region, forming a doped silicon layer region (18) on the insulating layer region (17?), and forming an insulating outside sidewall spacer (61) on the monocrystalline silicon region, where the outside sidewall spacer surrounds the doped silicon layer region to provide an isolation between the doped silicon layer region and exposed portions of the monocrystalline silicon region. The monocrystalline silicon region (13?), the insulating layer region (17?), and the doped silicon layer region (18) constitute a lower electrode, a dielectric, and an upper electrode of the capacitor.

Abstract: Semiconductor-on-diamond (SOD) substrates and methods for making such substrates are provided. In one aspect, a method of making an SOD substrate may include depositing a base layer onto a lattice-orienting silicon (Si) substrate such that the base layer lattice is substantially oriented by the Si substrate, depositing a semiconductor layer onto the base layer such that the semiconductor layer lattice is substantially oriented with respect to the base layer lattice, and disposing a layer of diamond onto the semiconductor layer. The base layer may include numerous materials, including, without limitation, aluminum phosphide (AlP), boron arsenide (BAs), gallium nitride (GaN), indium nitride (InN), and combinations thereof. Additionally, the method may further include removing the lattice-orienting Si substrate and the base layer from the semiconductor layer. In one aspect, the Si substrate may be of a single crystal orientation.

Abstract: A semiconductor substrate that includes a relatively thin monocrystalline useful layer, an intermediate layer transferred from a source substrate, and a relatively thick layer of a support present on one of the useful layer of the intermediate layer. The support is made of a deposited material that has a lower quality than that of one or both of the intermediate and useful layers. A bonding layer may be included on one of the intermediate layer or the useful layer, or both, to facilitate bonding of the layers an a thin layer may be provided between the useful layer and intermediate layer. These final substrates are useful in optic, electronic, or optoelectronic applications.

Abstract: Silicon carbide semiconductor devices and methods of fabricating silicon carbide semiconductor devices are provided by successively etching a mask layer to provide windows for formation of a source region of a first conductivity type, a buried silicon carbide region of a second conductivity type opposite to the first conductivity type and a second conductivity type well region in a first conductivity type silicon carbide layer. The source region and the buried silicon carbide region are formed utilizing a first window of the mask layer. Then, the well region is formed utilizing a second window of the mask layer, the second window being provided by a subsequent etch of the mask layer having the first window.

Abstract: Transistors and methods of manufacture thereof are disclosed. A workpiece is provided, a gate dielectric is formed over the workpiece, and a gate is formed over the gate dielectric by exposing the workpiece to a precursor of hafnium (Hf) and a precursor of silicon (Si). The gate includes and include respectively a layer of a combination of Hf and Si. The layer of the combination of Hf and Si of the gate establishes the threshold voltage Vt of the transistor. The transistor may includes and include respectively a single NMOS transistor or an NMOS transistor of a CMOS device.

Abstract: A thin film device includes a metal sulfide layer formed on a single crystal silicon substrate by epitaxial growth; and a compound thin film with ionic bonding, which is formed on the metal sulfide layer by epitaxial growth. Alternatively, a thin film device includes a metal sulfide layer formed on a single crystal silicon substrate by epitaxial growth; and at least two compound thin films with ionic bonding, which are formed on the metal sulfide layer by epitaxial growth. For example, (11 20) surface AlN/MnS/Si (100) thin films formed by successively stacking a MnS layer (about 50 nm thick) and an AlN layer (about 1000 nm thick) on a single crystal Si (100) substrate, are used as a substrate, and a (11 20) surface GaN layer (about 100 nm thick) operating as a light emitting layer is formed on the substrate, thereby fabricating a thin film device.

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.