Abstract: A compound semiconductor device and method of fabricating the same according to the present invention is disclosed. The compound semiconductor device comprises a substrate having at least a first doped region and at least a second doped region, and a semiconductor layer disposed on the substrate, wherein doping conditions of said first doped region and said second doped region may be different from each other.

Abstract: A method for producing a semiconductor layer is disclosed. One embodiment provides for a semiconductor layer on a semiconductor substrate containing oxygen. Crystal defects are produced at least in a near-surface region of the semiconductor substrate. A thermal process is carried out wherein the oxygen is taken up at the crystal defects. The semiconductor layer is deposited epitaxially over the near-surface region of the semiconductor substrate.

Abstract: A substrate for a light emitting diode (LED) can have one or more trenches formed therein so as to mitigate stress build up within the substrate due to mismatched thermal coefficients of expansion between the substrate and layers of material, e.g., semiconductor material, formed thereon. In this manner, the likelihood of damage to the substrate, such as cracking thereof, is substantially mitigated.

Abstract: An edge trimming method includes providing a semiconductor wafer having a front side and a backside, trimming an edge of a periphery of the semiconductor wafer from the front side to form at least a notch region around the periphery of the front side of the semiconductor wafer, and providing the front side of the semiconductor wafer to a handle wafer. The notch region comprises a first wall and a second wall, and the first and the second wall are perpendicular to each other.

Abstract: A semiconductor device includes a semiconductor substrate having an etch target layer provided on the surface thereof, and a hard mask layer formed over the etch target layer and including silicon, wherein the hard mask layer includes a dual structure including a first area and a second area having a larger etch rate than the first area, in order to increase an etching selectivity of the hard mask layer.

Abstract: A method of forming a nonvolatile memory cell includes forming a first electrode and a second electrode of the memory cell. Sacrificial material is provided between the first second electrodes. The sacrificial material is exchanged with programmable material. The sacrificial material may additionally be exchanged with select device material.

Abstract: A cavity is etched from a front surface into a semiconductor substrate. After providing an etch stop structure at the bottom of the cavity, the cavity is closed. From a back surface opposite to the front surface the semiconductor substrate is grinded at least up to an edge of the etch stop structure oriented to the back surface. Providing the etch stop structure at the bottom of an etched cavity allows for precisely adjusting a thickness of a semiconductor body of a semiconductor device.

Abstract: Aspects of the disclosure provide a method of inhibiting crack propagation in a silicon wafer. In one embodiment, a method of repairing an imperfection on a surface of a semiconductor device is disclosed. The method includes: screening for imperfections on a surface of a silicon wafer of a semiconductor device; and in response to at least one imperfection on the surface of the silicon wafer, depositing a material on the surface of the silicon wafer.

Abstract: A semiconductor device includes a wiring substrate having an insulating film formed on a surface thereof, a first semiconductor chip mounted on the wiring substrate, and a second semiconductor chip stacked and mounted on the first semiconductor chip so as to form an overhang portion. The insulating film is removed from an area of the wiring substrate that faces the overhang portion.

Abstract: A memory array that includes access devices that are each electrically coupled to more than one memory cell. The memory cells are coupled to the access devices via diode devices. The access devices include vertical semiconductor material mesas upstanding from a semiconductor base that form a conductive channel between first and second doped regions, and also planar access devices.

Abstract: According to one embodiment, a method for manufacturing a semiconductor device includes forming semiconductor layers in a plurality of first regions on a semiconductor wafer. The plurality of first regions are separated from each other. The method includes forming elements in the semiconductor layers. The method includes bonding an insulating plate made of an inorganic material in a second region on the semiconductor wafer. The second region excludes the first regions. The method includes performing singulation for each of the semiconductor layers by cutting the semiconductor wafer and the insulating plate along a dicing line configured to pass through only the second region.

Abstract: A method of manufacturing a semiconductor device includes preparing a semiconductor wafer including a silicon substrate and a laminate having a compound semiconductor layer; etching and removing a part of the laminate in a thickness direction to form trench regions in a grid, each trench region including a plurality of stripe grooves extending in parallel to each other; filling the groove with a material having a lower hardness than the compound semiconductor layer to form a buried region; and dividing the semiconductor wafer into a plurality of chips by dicing using a blade at a dicing line which is defined within the trench region and includes a plurality of the buried regions.

Abstract: A corner layout for a semiconductor device that maximizes the breakdown voltage is disclosed. The device includes first and second subsets of the striped cell arrays. The ends of each striped cell in the first array is spaced a uniform distance from the nearest termination device structure. In the second subset, the ends of striped cells proximate a corner of the active cell region are configured to maximize breakdown voltage by spacing the ends of each striped cell a non-uniform distance from the nearest termination device structure. It is emphasized that this abstract is provided to comply with the rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: A method includes structuring a semiconductor substrate to produce a number semiconductor chips. Each of the semiconductor chips includes a first main face and a number of side faces. An indentation is formed at a transition between the first main face and the side faces.

Abstract: The present invention addresses the problem of providing a novel silicon substrate having a textured surface by dry-etching the surface of a silicon substrate having (111) orientation and thereby forming a texture thereon. The present invention provides a silicon substrate having (111) orientation, said silicon substrate having a textured surface that includes multiple protrusions which each comprise three slant faces and have heights of 100 to 8000 nm. This process for producing a silicon substrate includes: a step of preparing a silicon substrate having (111) orientation; and a step of blowing an etching gas onto the surface of the silicon substrate, said etching gas containing one or more gases selected from the group consisting of ClF3, XeF2, BrF3, BrF5 and NF3.

Abstract: An object is to provide an SOI substrate provided with a semiconductor layer which can be used practically even when a glass substrate is used as a base substrate. Another object is to provide a semiconductor device having high reliability using such an SOI substrate. An altered layer is formed on at least one surface of a glass substrate used as a base substrate of an SOI substrate to form the SOI substrate. The altered layer is formed on at least the one surface of the glass substrate by cleaning the glass substrate with solution including hydrochloric acid, sulfuric acid or nitric acid. The altered layer has a higher proportion of silicon oxide in its composition and a lower density than the glass substrate.

Abstract: A method is demonstrated to form an SOI substrate having a silicon layer with reduced surface roughness in a high yield. The method includes the step of bonding a base substrate such as a glass substrate and a bond substrate such as a single crystal semiconductor substrate to each other, where a region in which bonding of the base substrate with the bond substrate cannot be performed is provided at the interface therebetween. Specifically, the method is exemplified by the combination of: irradiating the bond substrate with accelerated ions; forming an insulating layer over the bond substrate; forming a region in which bonding cannot be performed in part of the surface of the bond substrate; bonding the bond substrate and the base substrate to each other with the insulating layer therebetween; and separating the bond substrate from the base substrate, leaving a semiconductor layer over the base substrate.

Abstract: One or more heat pipes are utilized along with a substrate in order to provide heat dissipation through the substrate for heat that can build up at an interface between the substrate and one or more semiconductor chips in a package. In an embodiment the heat pipe may be positioned on a side of the substrate opposite the semiconductor chip and through-substrate vias may be utilized to dissipate heat through the substrate. In an alternative embodiment, the heat pipe may be positioned on a same side of the substrate as the semiconductor chip and may be thermally connected to the one or more semiconductor chips.

Abstract: Methods of dicing semiconductor wafers, and transporting singulated die, are described. In an example, a method of dicing a wafer having a plurality of integrated circuits thereon involves dicing the wafer into a plurality of singulated dies disposed above a dicing tape. The method also involves forming a water soluble material layer over and between the plurality of singulated dies, above the dicing tape.

Abstract: A method of manufacturing a single crystal ingot, and a single crystal ingot and a wafer manufactured thereby are provided. The method of manufacturing a single crystal ingot according to an embodiment includes forming a silicon melt in a crucible inside a chamber, preparing a seed crystal on the silicon melt, and growing a single crystal ingot from the silicon melt, and pressure of the chamber may be controlled in a range of 90 Torr to 500 Torr.

Abstract: Closed loop control may be used to improve uniformity of within wafer uniformity using chemical mechanical planarization. For example, closed loop control may be used to determine a control profile for a chemical mechanical planarization process to more uniformly and consistently achieve the desired extent of variation of within wafer uniformity of a semiconductor wafer.

Abstract: A method of removing at least one oxide from a surface of a body of semiconductor material is disclosed, the method comprising: arranging the body in a vacuum chamber; and maintaining a temperature of the body in the vacuum chamber within a predetermined range, or substantially at a predetermined value, while exposing said surface to a flux of indium atoms. Corresponding methods of processing an oxidised surface of a body of semiconductor material to prepare the surface for epitaxial growth of at least one epitaxial layer or film over said surface, and methods of manufacturing a semiconductor device are also disclosed.

Abstract: An epitaxial growth method includes the steps of: providing a substrate; forming a sacrifice layer on the substrate; patterning the sacrifice layer to form a plurality of bumps spaced apart from each other on the substrate; epitaxially forming a first epitaxial layer on the substrate to cover a portion of each of the bumps; removing the bumps to form a plurality of cavities; and epitaxially forming a second epitaxial layer on the first epitaxial layer such that the cavities are enclosed by the first epitaxial layer and the second epitaxial layer. An epitaxial structure grown by the method is disclosed as well.

Abstract: According to one embodiment, a semiconductor device comprises an active area extending in a first direction, a contact plug located on a first portion of the active area, and a transistor located on a second portion adjacent to the first portion of the active area in the first direction. A width of a top surface area of the first portion in a second direction perpendicular to the first direction is smaller than that of a top surface area of the second portion in the second direction.

Abstract: Described herein are composite semiconductor substrates for use in semiconductor device fabrication and related devices and methods. In one embodiment, a composite substrate includes: (1) a bulk silicon layer; (2) a porous silicon layer adjacent to the bulk silicon layer, wherein the porous silicon layer has a Young's modulus value that is no greater than 110.5 GPa; (3) an epitaxial template layer, wherein the epitaxial template layer has a root-mean-square surface roughness value in the range of 0.2 nm to 1 nm; and (4) a set of silicon nitride layers disposed between the porous silicon layer and the epitaxial template layer.

Abstract: An integrated fin-based field effect transistor (FinFET) and method of fabricating such devices on a bulk wafer with EPI-defined fin heights over shallow trench isolation (STI) regions. The FinFET channels overlie the STI regions within the semiconductor bulk, while the fins extend beyond the STI regions into the source and drain regions which are implanted within the semiconductor bulk. With bulk source and drain regions, reduced external FinFET resistance is provided, and with the fins extending into the bulk source and drain regions, improved thermal properties is provided over conventional silicon on insulator (SOI) devices.

Abstract: A semiconductor device has a first layer formed on a substrate. A mask layer is formed and patterned above the first layer. The first layer is etched partially through. A second layer is formed over the first layer. The first and second layers are etched by a non-lithography process.

Abstract: The invention provides a method for manufacturing a bonded substrate by bonding a base substrate to a bond substrate through an insulator film, including: a porous layer forming step of partially forming a porous layer or forming a porous layer whose thickness partially varies on a bonding surface of the base substrate; an insulator film forming step of changing the porous layer into the insulator film, and thereby forming the insulator film whose thickness partially varies on the bonding surface of the base substrate; a bonding step of bonding the base substrate to the bond substrate through the insulator film; and a film thickness reducing step of reducing a film thickness of the bonded bond substrate to form a thin-film layer. As a result, there is provided the method for manufacturing a bonded substrate that enables obtaining an insulator film whose thickness partially varies with use of a simple method.

Abstract: A system and method for aligning a probe, such as a wafer-level test probe, with wafer contacts is disclosed. An exemplary method includes receiving a wafer containing a plurality of alignment contacts and a probe card containing a plurality of probe points at a wafer test system. A historical offset correction is received. Based on the historical offset correct, an orientation value for the probe card relative to the wafer is determined. The probe card is aligned to the wafer using the orientation value in an attempt to bring a first probe point into contact with a first alignment contact. The connectivity of the first probe point and the first alignment contact is evaluated. An electrical test of the wafer is performed utilizing the aligned probe card, and the historical offset correction is updated based on the orientation value.

Abstract: An etching liquid for texturing a silicon wafer surface is provided. The etching liquid may include an aqueous solution of at least one alkaline etching agent and at least one polysaccharide or derivative thereof. Also provided is a process for texture etching a silicon wafer using the etching liquid of the invention.

Abstract: In one embodiment, an apparatus includes a three dimensional structure comprising a semiconductor material, and at least one thin film in contact with at least one exterior surface of the three dimensional structure for inducing a strain in the structure, the thin film being characterized as providing at least one of: an induced strain of at least 0.05%, and an induced strain in at least 5% of a volume of the three dimensional structure. In another embodiment, a method includes forming a three dimensional structure comprising a semiconductor material, and depositing at least one thin film on at least one surface of the three dimensional structure for inducing a strain in the structure, the thin film being characterized as providing at least one of: an induced strain of at least 0.05%, and an induced strain in at least 5% of a volume of the structure.

Abstract: A semiconductor structure includes a first semiconductor layer, an active layer, a second semiconductor layer, and a cermet layer stacked together. The active layer is on a surface of the first semiconductor layer. The second semiconductor layer is on a surface of the active layer away from the first semiconductor layer. The cermet layer is on a surface of the second semiconductor layer away from the first semiconductor layer.

Abstract: A semiconductor structure includes a first semiconductor layer, an active layer, a second semiconductor layer, a metallic plasma generating layer, and a first optical symmetric layer stacked in series. The first semiconductor layer, the active layer, and the second semiconductor layer constitute a source layer. A refractive index difference between the source layer and the first optical symmetric layer is less than or equal to 0.3.

Abstract: A semiconductor device and a method of fabricating the same, includes vertically stacked layers on an insulator. Each of the layers includes a first dielectric insulator portion, a first metal conductor embedded within the first dielectric insulator portion, a first nitride cap covering the first metal conductor, a second dielectric insulator portion, a second metal conductor embedded within the second dielectric insulator portion, and a second nitride cap covering the second metal conductor. The first and second metal conductors form first vertically stacked conductor layers and second vertically stacked conductor layers. The first vertically stacked conductor layers are proximate the second vertically stacked conductor layers, and at least one air gap is positioned between the first vertically stacked conductor layers and the second vertically stacked conductor layers.

Abstract: The invention provides methods and devices for fabricating printable semiconductor elements and assembling printable semiconductor elements onto substrate surfaces. Methods, devices and device components of the present invention are capable of generating a wide range of flexible electronic and optoelectronic devices and arrays of devices on substrates comprising polymeric materials. The present invention also provides stretchable semiconductor structures and stretchable electronic devices capable of good performance in stretched configurations.

Abstract: A semiconductor processing method that can generate a hole with different diameters, comprising: providing first material and second material different from the first material; and utilizing a etching process to etch the first material and the second material to form a hole through the first material and the second material; wherein the etching process has different etching rates for the first material and the second material such that the hole have different diameters. A semiconductor structure corresponding to the above-mentioned method is also disclosed.

Abstract: A semiconductor device is manufactured by forming at least one epitaxial structure over a substrate. A portion of the substrate is cut and lifted to expose a partial surface of the epitaxial structure. A first electrode is then formed on the exposed partial surface to result in a vertical semiconductor device.

Abstract: A method of manufacturing is disclosed. An exemplary method includes providing a substrate and forming one or more layers over the substrate. The method further includes forming a surface layer over the one or more layers. The method further includes performing a patterning process on the surface layer thereby forming a pattern on the surface layer. The method further includes performing a cleaning process using a cleaning solution to clean a top surface of the substrate. The cleaning solution includes tetra methyl ammonium hydroxide (TMAH), hydrogen peroxide (H2O2) and water (H2O).

Abstract: A semiconductor device and a method of fabricating a semiconductor device, wherein the method includes forming, on a substrate, a plurality of planarized fin bodies to be used for customized fin field effect transistor (FinFET) device formation; forming a nitride spacer around each of the plurality of fin bodies; forming an isolation region in between each of the fin bodies; and coating the plurality of fin bodies, the nitride spacers, and the isolation regions with a protective film. The fabricated semiconductor device is adapted to be used in customized applications as a customized semiconductor device.

Abstract: A stressor layer used in a controlled spalling method is removed through the use of a cleave layer that can be fractured or dissolved. The cleave layer is formed between a host semiconductor substrate and the metal stressor layer. A controlled spalling process separates a relatively thin residual host substrate layer from the host substrate. Following attachment of a handle substrate to the residual substrate layer or other layers subsequently formed thereon, the cleave layer is dissolved or otherwise compromised to facilitate removal of the stressor layer. Such removal allows the fabrication of a bifacial solar cell.

Abstract: A method for manufacturing a semiconductor device includes: (a) providing a base unit made of a material having a first lattice constant; (b) forming a first sacrificial layer made of a material having a second lattice constant on the base unit and a second sacrificial layer made of a material having a third lattice constant on the first sacrificial layer, the first lattice constant ranging between the second and third lattice constants so that two lattice stresses in opposite directions occur in the epitaxial substrate; (c) forming an epitaxial unit on the second sacrificial layer; (d) forming a permanent substrate on the epitaxial unit; and (e) removing the epitaxial unit.

Abstract: The invention relates to a method for texturing the surface of a gaseous phase silicon substrate, and to a textured silicon substrate for a solar cell. The method includes at least a step a) of exposing the surface to an SF6/O2 radiofrequency plasma for a duration of 2 to 30 minutes in order to produce a silicon substrate having a textured surface having pyramidal structures, the SF6/O2 ratio being 2 to 10. During step a) the power density generated using the radiofrequency plasma is greater than or equal to 2500 mW/cm2, and the SF6/O2 pressure in the reaction chamber is lower than or equal to 100 mTorrs, so as to produce a silicon substrate having a textured surface having inverted pyramidal structures.

Abstract: A semiconductor device includes a semiconductor body having a first surface and a second surface opposite to the first surface. A superjunction structure in the semiconductor body includes drift regions of a first conductivity type and compensation structures alternately disposed in a first direction parallel to the first surface. Each of the charge compensation structures includes a first semiconductor region of a second conductivity type complementary to the first conductivity type and a first trench including a second semiconductor region of the second conductivity type adjoining the first semiconductor region. The first semiconductor region and the first trench are disposed one after another in a second direction perpendicular to the first surface.

Abstract: Provided is a semiconductor device. The semiconductor device comprises a support substrate; a bonding layer on the support substrate; and a plurality of semiconductor layers on the bonding layer, wherein the bonding layer includes a first bonding layer between the support substrate and the plurality of semiconductor layers and a second bonding layer between the first bonding layer and the plurality of semiconductor layers, wherein an at least one of the first and second bonding layers includes a multi layers, wherein the first and second bonding layers include a same material from each other, wherein the first and second bonding layers includes a different material from the plurality of semiconductor layers.

Abstract: A method for formation of a fin field effect transistor (FinFET) device includes forming a mandrel mask on a metal hardmask layer of a film stack, the film stack including a silicon on insulator (SOI) layer located underneath the metal hardmask layer; forming a large feature (FX) mask on the metal hardmask layer; etching the mandrel mask and the FX mask simultaneously into the metal hardmask layer; etching the mandrel mask and the FX mask into the SOI layer using the etched metal hardmask layer as a mask.

Abstract: A film formation substrate (200) is a film formation substrate having a plurality of vapor deposition regions (24R and 24G) (i) which are arranged along a predetermined direction and (ii) in which respective vapor-deposited films (23R and 23G) are provided. The vapor-deposited film (24R) has inclined side surfaces 23s which are inclined with respect to a direction normal to the film formation substrate (200). A width, in the predetermined direction, of the vapor-deposited film (23R) is larger than the sum of (i) a width, in the predetermined direction, of the vapor deposition region (24R) and (ii) a width, in the predetermined direction, of a region (29) between the vapor deposition region (24R) and the vapor deposition region (24G).

Abstract: A method that includes, in the sequence set forth, (1) temporarily fixing a substrate onto a support via a temporary fixing material including a central section (A) having two or more layers and a peripheral section (B) with solvent resistance, section (B) being in contact with a peripheral portion of the support on the substrate side and with a peripheral portion of the substrate on the support side, section (A) being in contact with a central portion of the support on the substrate side and with a central portion of the substrate on the support side, the temporary fixing thus resulting in a stack in which section (A) is covered with the support, section (B) and the substrate; (2) processing the substrate and/or transporting the stack; (3) dissolving section (B) with a solvent; and (4) heating the residue of the temporary fixing material and separating the substrate from the support.

Abstract: A technique is provided for a structure. A substrate has a nanopillar vertically positioned on the substrate. A bottom layer is formed beneath the substrate. A top layer is formed on top of the substrate and on top of the nanopillar, and a cover layer covers the top layer and the nanopillar. A window is formed through the bottom layer and formed through the substrate, and the window ends at the top layer. A nanopore is formed through the top layer by removing the cover layer and the nanopillar.

Abstract: A method of forming an array of nanostructures includes forming a plurality of seed points on a surface of a substrate, and growing masks from the seed points to create masked regions of the substrate underlying the masks. A remainder of the substrate comprises an unmasked region. Each mask and masked region increase in size with growth time while the unmasked region of the substrate decreases in size. During the growing, the unmasked region is etched to remove material from the substrate in a depth direction, and, simultaneously, unetched structures are formed from the masked regions of the substrate underlying the masks. Each of the unetched structures has a lateral size that increases with depth.

Abstract: A method for formation of a fin field effect transistor (FinFET) device includes forming a mandrel mask and a large feature (FX) mask on a metal hardmask layer of a film stack, the film stack including a silicon on insulator (SOI) layer located underneath the metal hardmask layer; etching the mandrel mask and the FX mask simultaneously into the metal hardmask layer; and etching the mandrel mask and the FX mask into the SOI layer using the etched metal hardmask layer as a mask.