Abstract: A method of providing a layer of solid electrolyte comprises providing a host substrate including a crystalline solid electrolyte layer, and transferring the crystalline solid electrolyte layer from the host substrate to a receiver substrate. The method may be used to manufacture various devices, such as solid oxide fuel cells, oxygen sensors, batteries, and donor structures.

Abstract: Electromechanical device structures are provided, as well as methods for forming them. The device structures incorporate at least a first and second substrate separated by an interface material layer, where the first substrate comprises an anchor material structure and at least one suspended material structure, optionally a spring material structure, and optionally an electrostatic sense electrode. The device structures may be formed by methods that include providing an interface material layer on one or both of the first and second substrates, bonding the interface materials to the opposing first or second substrate or to the other interface material layer, followed by forming the suspended material structure by etching.

Abstract: A technique relates to manufacturing a finFET device. A plurality of first and second semiconductor fins are formed on a substrate. Gate stacks are formed on the substrate, each including a gate, a hard mask and an oxide layer. A dielectric spacer layer is deposited. A sacrificial fill material is deposited on the finFET device and planarized. A second hard mask is deposited, a trench area is patterned in the hard mask parallel to the first and second semiconductor fins, and the sacrificial fill material is anisotropically etched to create a trench. A dielectric wall is formed in the trench and the second hard mask and sacrificial fill material are removed.

Abstract: A semiconductor device includes a source/drain feature in a substrate. The source/drain feature has an upper portion and a lower portion, the upper portion having a lower concentration of Ge than the lower portion. A Si-containing layer over the source/drain feature includes a metal silicide layer.

Abstract: A silicon carbide substrate having a main face is prepared. By applying thermal oxidation to the main face of the silicon carbide substrate at a first temperature, an oxide film is formed on the main face. After the oxide film is formed, heat treatment is applied to the silicon carbide substrate at a second temperature higher than the first temperature. An opening exposing a portion of the main face is formed at the oxide film. A Schottky electrode is formed on the main face exposed by the opening.

Abstract: A semiconductor device with an n-type transistor and a p-type transistor having an active region is provided. The active region further includes two adjacent gate structures. A portion of a dielectric layer between the two adjacent gate structures is selectively removed to form a contact opening having a bottom and sidewalls over the active region. A bilayer liner is selectively provided within the contact opening in the n-type transistor and a monolayer liner is provided within the contact opening in the p-type transistor. The contact opening in the n-type transistor and p-type transistor is filled with contact material. The monolayer liner is treated to form a silicide lacking nickel in the p-type transistor.

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 finFET device is provided. The finFET device includes a BOX layer, fin structures located over the BOX layer, a gate stack located over the fin structures, gate spacers located on vertical sidewalls of the gate stack, an epi layer covering the fin structures, source and drain regions located in the semiconductor layers of the fin structures, and silicide regions abutting the source and drain regions. The fin structures each comprise a semiconductor layer and extend in a first direction, and the gate stack extends in a second direction that is perpendicular. The gate stack comprises a high-K dielectric layer and a metal gate, and the epi layer merges the fin structures together. The silicide regions each include a vertical portion located on the vertical sidewall of the source or drain region.

Abstract: A semiconductor device includes a MOS transistor, a source electrode and a drain electrode on the MOS transistor each include a first carbon doped silicon layer including carbon at a first carbon concentration and phosphorus at a first phosphorus concentration and a second carbon doped silicon layer over the first silicon carbide layer, which includes phosphorus at a second phosphorus concentration higher than the first phosphorus concentration, and which includes carbon at a second carbon concentration less than or equal to the first carbon concentration.

Abstract: A semiconductor device includes a MOS transistor, a source electrode and a drain electrode on the MOS transistor each include a first carbon doped silicon layer including carbon at a first carbon concentration and phosphorus at a first phosphorus concentration and a second carbon doped silicon layer over the first silicon carbide layer, which includes phosphorus at a second phosphorus concentration higher than the first phosphorus concentration, and which includes carbon at a second carbon concentration less than or equal to the first carbon concentration.

Abstract: A semiconductor optical element having a mesa structure formed by wet etching, includes a mesa structure having a ridge-type mesa structure or a high-mesa-type mesa structure, the mesa structure being disposed on a semiconductor substrate, and an extended mesa on the semiconductor substrate, the extended mesa being connected to a corner of the mesa structure and being the same material as the mesa structure.

Abstract: A method is provided for fabricating a finFET device. Fin structures are formed over a BOX layer. The fin structures include a semiconductor layer and extend in a first direction. A gate stack is formed on the BOX layer over the fin structures and extending in a second direction. The gate stack includes a high-K dielectric layer and a metal gate. Gate spacers are formed on sidewalls of the gate stack, and an epi layer is deposited to merge the fin structures. Ions are implanted to form source and drain regions, and dummy spacers are formed on sidewalls of the gate spacers. The dummy spacers are used as a mask to recess or completely remove an exposed portion of the epi layer. Silicidation forms silicide regions that abut the source and drain regions and each include a vertical portion located on the vertical sidewall of the source or drain region.

Abstract: A semiconductor device having tipless epitaxial source/drain regions and a method for its formation are described. In an embodiment, the semiconductor device comprises a gate stack on a substrate. The gate stack is comprised of a gate electrode above a gate dielectric layer and is above a channel region in the substrate. The semiconductor device also comprises a pair of source/drain regions in the substrate on either side of the channel region. The pair of source/drain regions is in direct contact with the gate dielectric layer and the lattice constant of the pair of source/drain regions is different than the lattice constant of the channel region. In one embodiment, the semiconductor device is formed by using a dielectric gate stack placeholder.

Abstract: Semiconductor material is formed on a host substrate of a material exhibiting optical transparency with an intervening radiation lift off layer. A transfer device, intermediate substrate or target substrate is brought into adhesive contact with the semiconductor material and the radiation lift off layer is irradiated to weaken it, allowing the semiconductor material to be transferred off the host substrate. Electronic devices may be formed in the semiconductor layer while it is attached to the host substrate or the intermediate substrate.

Abstract: A multilevel interconnect structure in a semiconductor device includes a first insulating layer formed on a semiconductor wafer, a Cu interconnect layer formed on the first insulating layer, a second insulating layer formed on the Cu interconnect layer, and a metal oxide layer formed at an interface between the Cu interconnect layer and the second insulating layer. The metal oxide layer is formed by immersion-plating a metal, such as Sn or Zn, on the Cu interconnect layer and then heat-treating the plated layer in an oxidizing atmosphere.

Abstract: A silicon carbide semiconductor device having excellent performance characteristics and a method of manufacturing the same are obtained. An extended terrace surface is formed at a surface of an initial growth layer on a 4H—SiC substrate by annealing with the initial growth layer covered with an Si film, and then a new growth layer is epitaxially grown on the initial growth layer. A 3C—SiC portion having a polytype stable at a low temperature is grown on the extended terrace surface, and a 4H—SiC portion is grown on the other region. A trench is formed by selectively removing the 3C—SiC portion with the 4H—SiC portion remaining, and a gate electrode of a UMOSFET is formed in the trench. A channel region of the UMOSFET can be controlled to have a low-order surface, and a silicon carbide semiconductor device having high channel mobility and excellent performance characteristics is obtained.

Abstract: Intermediate structures are provided that are formed during the manufacture of a memory device. These structures include first and second spaced apart gate patterns on a semiconductor substrate. A source/drain region is provided in the semiconductor substrate between the first and second gate patterns. An etch stop layer is provided on first and second sidewalls of the first gate pattern. The first and second sidewalls face each other to define a gap region between the etch stop layer on the first sidewall and the etch stop layer on the second sidewall. A dielectric layer is provided in the gap region. Finally, a preliminary contact hole is provided in the dielectric layer.

Abstract: A method of manufacturing a silicon carbide semiconductor device is disclosed in which a trench and a hole are controlled to have a predetermined configuration even if the silicon carbide semiconductor device is subjected to a heat treatment at a temperature of not lower than 1,500° C. A heat treatment step(s) of a method of the invention includes a step of heat treatment in an argon atmosphere at a temperature in a range of 1,600° C. to 1,800° C. under a pressure of at most 10 Torr for a time duration in a range of 0.1 min to 10 min to evaporate silicon atoms from a surface of the silicon carbide semiconductor substrate or the silicon carbide epitaxial layer and to obtain a silicon carbide surface with a carbon atom concentration of at least 95%.

Abstract: A multi-step etching process produces trench openings in a silicon substrate that are immediately adjacent transistor structures formed over the substrate surface. The multi-step etching process is a Br-based etching operation with one step including nitrogen and a further step deficient of nitrogen. The etching process does not attack the transistor structure and forms an opening bounded by upper surfaces that extend downwardly from the substrate surface and are substantially vertical, and lower surfaces that bulge outwardly from the upper vertical sections and undercut the transistor structure. The aggressive undercut produces a desirable stress in the etched silicon surface. The openings are then filled with a suitable source/drain material and SSD transistors with desirable Idsat characteristics may then be formed.

Abstract: An electronic device includes a silicon carbide layer including an n-type drift region therein, a contact forming a junction, such as a Schottky junction, with the drift region, and a p-type junction barrier region on the silicon carbide layer. The p-type junction barrier region includes a p-type polysilicon region forming a P-N heterojunction with the drift region, and the p-type junction barrier region is electrically connected to the contact. Related methods are also disclosed.

Abstract: A method of manufacturing a silicon carbide semiconductor device is disclosed in which a trench and a hole are controlled to have a predetermined configuration even if the silicon carbide semiconductor device is subjected to a heat treatment at a temperature of not lower than 1,500° C. A heat treatment step(s) of a method of the invention includes a step of heat treatment in an argon atmosphere at a temperature in a range of 1,600° C. to 1,800° C. under a pressure of at most 10 Torr for a time duration in a range of 0.1 min to 10 min to evaporate silicon atoms from a surface of the silicon carbide semiconductor substrate or the silicon carbide epitaxial layer and to obtain a silicon carbide surface with a carbon atom concentration of at least 95%.

Abstract: A method of fabricating a MOS transistor having a thinned channel region is described. The channel region is etched following removal of a dummy gate. The source and drain regions have relatively low resistance with the process.

Abstract: A method for fabricating a selective area metal bonding Si-based laser, optically or electrically pumped includes: forming a Si waveguide area and a bonding area in a Silicon-On-Insulator (SOI) wafer, and forming an isolating structure to separate the Si waveguide area from the bonding area; forming a metal multilayer for bonding, which also acts as ohmic contact layer in the laser when the laser is electrically pumped. A compound semiconductor optical gain structure is prepared by epitaxial growth and etched off the substrate. The compound semiconductor optical gain structure is aligned with the Si waveguide area in the SOI wafer and the compound semiconductor optical gain structure is bonded on the SOI wafer. The selective area metal bonding Si-based laser can be used as a light source in optoelectronic integration and Si photonics. The method may provide simple operation, flexibility, low cost, and low requirement for cleanness of manufacturing environments.

Abstract: It is an object of the present invention to provide a semiconductor device including a wiring having a preferable shape. A manufacturing method includes the steps of forming a first conductive layer connected to an element and a second conductive layer thereover; forming a resist mask over the second conductive layer; processing the second conductive layer by dry etching with the use of the mask; and processing the first conductive layer by wet etching with the mask left, wherein the etching rate of the second conductive layer is higher than that of the first conductive layer in the dry etching, and wherein the etching rate of the second conductive layer is the same as or more than that of the first conductive layer in the wet etching.

Abstract: A process for forming defect-free source and drain extensions for a MOSFET built on a germanium based channel region deposits a first silicon germanium layer on a semiconductor substrate, deposits a gate dielectric layer on the silicon germanium layer, and deposits a gate electrode layer on the gate dielectric layer. A dry etch chemistry etches those layers to form a gate electrode, a gate dielectric, and a silicon germanium channel region on the semiconductor substrate. Next, an ion implantation process forms halo implant regions that consume portions of the silicon germanium channel region and the semiconductor substrate. Finally, an in-situ doped epitaxial deposition process grows a pair of silicon germanium layers having LDD regions. The silicon germanium layers are adjacent to the silicon germanium channel region and the halo implant regions do not damage any portion of the silicon germanium layers.

Abstract: An aluminum gallium nitride/gallium nitride layer (III-V nitride semiconductor layer) is formed on the surface of a silicone carbide substrate. The aluminum gallium nitride/gallium nitride layer is dry-etched from an exposed surface, using a chlorine-based gas (first gas) and a surface via hole is thereby formed. A back via hole, which is to be connected to the surface via hole, is formed by dry-etching the silicon carbide substrate from an exposed back side using a fluorine-based gas (second gas).

Abstract: A resistance type memory device is provided. The resistance type memory device is disposed on a substrate and includes a tungsten electrode, an upper electrode, and a tungsten oxide layer. The upper electrode is disposed on the tungsten electrode. The tungsten oxide layer is sandwiched between the tungsten electrode and the upper electrode.

Abstract: A method for manufacturing a silicon carbide (SiC) semiconductor device is disclosed that uses dry etching with the use of high-density inductive coupled plasma (ICP). The method employs a first dry etching and a sequential second dry etching under conditions that differ from those used in the first dry etching. The dry etch process allows a trench to be deeply etched to a depth of more than 3 ?m in a SiC laminated semiconductor substrate and allows the bottom of the trench to be flat without forming a convexo-concave shape having an acute angle which has an influence on characteristics of a breakdown voltage due to electric field concentration being caused in the bottom.

Abstract: A method of forming and a structure of an electronic device. The method including: forming a trench in a single-crystal semiconductor substrate; forming a dopant diffusion barrier layer on sidewalls and a bottom of the trench; and epitaxially growing a single-crystal semiconductor layer in the trench, the single-crystal semiconductor layer filling the trench, the dopant diffusion barrier layer a barrier to diffusion of semiconductor dopants. Also a power transistor formed by the same method.

Abstract: MOS transistors having localized stressors for improving carrier mobility are provided. Embodiments of the invention comprise a gate electrode formed over a substrate, a carrier channel region in the substrate under the gate electrode, and source/drain regions on either side of the carrier channel region. The source/drain regions include an embedded stressor having a lattice spacing different from the substrate. In a preferred embodiment, the substrate is silicon and the embedded stressor is SiGe or SiC. An epitaxy process that includes using HCl gas selectively forms a stressor layer within the crystalline source/drain regions and not on polycrystalline regions of the structure. A preferred epitaxy process dispenses with the source/drain hard mask required of conventional methods. The embedded SiGe stressor applies a compressive strain to a transistor channel region. In another embodiment, the embedded stressor comprises SiC, and it applies a tensile strain to the transistor channel region.

Abstract: The present invention provides a semiconductor device, a method of manufacture therefore and a method for manufacturing an integrated circuit including the same. The semiconductor device, among other elements, may include a substrate (110), as well as a nickel silicide region (170) located over the substrate (110), the nickel silicide region (170) having an amount of indium located therein.

Abstract: The invention provides a semiconductor device, a method of manufacture therefore and a method for manufacturing an integrated circuit including the same. The semiconductor device, among other elements, may include a gate structure located over a substrate, the gate structure including a gate dielectric layer and gate electrode layer. The semiconductor device may further include source/drain regions located in/over the substrate and adjacent the gate structure, and a nickel alloy silicide located in the source/drain regions, the nickel alloy silicide having an amount of indium located therein.

Abstract: A storage capacitor plate for a semiconductor assembly comprising a substantially continuous porous conductive storage plate comprising silicon nanocrystals residing along a surface of a conductive material and along a surface of a coplanar insulative material adjacent the conductive material, a capacitor cell dielectric overlying the silicon nanocrystals and an overlying conductive top plate. The conductive storage plate is formed by a semiconductor fabrication method comprising forming silicon nanocrystals on a surface of a conductive material and on a surface of an insulative material adjacent the conductive material, wherein silicon nanocrystals contain conductive impurities and are adjoined to formed a substantially continuous porous conductive layer.

Abstract: Single crystal silicon is grown in a [100] direction to make a bulk. Next, a silicon substrate with a normal of a surface extending in an inclined direction from a [100] direction is cut from the bulk. At this time, when an angle (off-angle) of inclination of the normal is decomposed into a component in a [001] direction and a component in a [010] direction, the component in the [001] direction is made within ±0.2 degrees (excluding 0 degree). An MOS transistor with a moving direction of carriers being the [001] direction is formed on the surface of the silicon substrate. At this time, after steps existing on the surface of the silicon substrate are reconstituted by thermal treatment in a hydrogen atmosphere, a gate insulation film, a gate electrode and the like are formed.