Class / Patent application number | Description | Number of patent applications / Date published |
257623000 | Mesa structure (e.g., including undercut or stepped mesa configuration or having constant slope taper) | 82 |
20080246123 | METHODS FOR CONTROLLING CATALYST NANOPARTICLE POSITIONING AND APPARATUS FOR GROWING A NANOWIRE - A method for controlling catalyst nanoparticle positioning includes establishing a mask layer on a post such that a portion of a vertical surface of the post remains exposed. The method further includes establishing a catalyst nanoparticle material on the mask layer and directly adjacent at least a portion of the exposed portion of the vertical surface. | 10-09-2008 |
20080258269 | SEMICONDUCTOR WAFER AND METHOD FOR CUTTING THE SAME - A semiconductor wafer and a method for cutting the same, enabling separation of the semiconductor wafer by natural cleavage planes, are disclosed. The cutting method according to an embodiment of the present invention comprises preparing a substrate including a semiconductor layer with at least one projection, formed on a predetermined area thereof; forming a post on an upper surface of the semiconductor layer at one or both sides of the projection to be placed on a cleaving line for cutting of the semiconductor layer; and cutting the substrate including the semiconductor layer along the cleaving line by performing a scribing process in a direction from the substrate and a breaking process in a direction from the semiconductor layer. | 10-23-2008 |
20080296737 | Methods for Manufacturing a Structure on or in a Substrate, Imaging Layer for Generating Sublithographic Structures, Method for Inverting a Sublithographic Pattern, Device Obtainable by Manufacturing a Structure - One possible embodiment is a method of manufacturing a structure on or in a substrate with the following steps | 12-04-2008 |
20080308911 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD THEREOF - An object is to provide a semiconductor device with improved reliability in which a defect stemming from an end portion of a semiconductor layer provided in an island shape is prevented, and a manufacturing method thereof. Over a substrate having an insulating surface, an island-shaped semiconductor layer is formed, a first alteration treatment is performed, a first insulating film is formed on a surface of the island-shaped semiconductor layer, the first insulating film is removed, a second alteration treatment is performed on the island-shaped semiconductor from which the first insulating film is removed, a second insulating film is formed on a surface of the island-shaped semiconductor layer, and a conductive layer is formed over the second insulating film. An upper end portion of the island-shaped semiconductor layer has curvature by the first alteration treatment and the second alteration treatment. | 12-18-2008 |
20090026586 | Superjunction Device Having Oxide Lined Trenches and Method for Manufacturing a Superjunction Device Having Oxide Lined Trenches - A method of manufacturing a semiconductor device includes providing semiconductor substrate having trenches and mesas. At least one mesa has first and second sidewalls. The method includes doping with a dopant of a second conductivity the first sidewall of the mesa, and doping with a dopant of a second conductivity the second sidewall of the mesa. A dopant of the first conductivity is then used to dope the first sidewall of the mesa, and the dopant of the first conductivity is used to dope the second sidewall of the at least one mesa. At least the trenches adjacent to the at least one mesa are then lined with an oxide material and are then filled with one of a semi-insulating material and an insulating material. | 01-29-2009 |
20090032908 | Semiconductor device and method of manufacturing it - A method of manufacturing a semiconductor device capable of largely increasing the yield and a semiconductor device manufactured by using the method is provided. After a semiconductor layer is formed on a substrate, as one group, a plurality of functional portions with at least one parameter value different from each other is formed in the semiconductor layer for every unit chip area. Then, a subject that is changed depending on the parameter value is measured and evaluated and after that, the substrate is divided for every chip area so that a functional portion corresponding with a given criterion as a result of the evaluation is not broken. Thereby, at least one functional portion corresponding with a given criterion can be formed by every chip area by appropriately adjusting each parameter value. | 02-05-2009 |
20090057846 | METHOD TO FABRICATE ADJACENT SILICON FINS OF DIFFERING HEIGHTS - A method to fabricate adjacent silicon fins of differing heights comprises providing a silicon substrate having an isolation layer deposited thereon, patterning the isolation layer to form first and second isolation structures, patterning the silicon substrate to form a first silicon fin beneath the first isolation structure and a second silicon fin beneath the second isolation structure, depositing an insulating layer on the substrate, planarizing the insulating layer to expose top surfaces of the first and second isolation structures, depositing and patterning a masking layer to mask the first isolation structure but not the second isolation structure, applying a wet etch to remove the second isolation structure and expose the second silicon fin, epitaxially depositing a silicon layer on the second silicon fin, and recessing the insulating layer to expose at least a portion of the first silicon fin and at least a portion of the second silicon fin. | 03-05-2009 |
20090091002 | METHODS FOR PRODUCING IMPROVED EPITAXIAL MATERIALS - This invention provides methods for fabricating substantially continuous layers of group III nitride semiconductor materials having low defect densities. The methods include epitaxial growth of nucleation layers on a base substrate, thermally treatment of said nucleation layer and epitaxial growth of a discontinuous masking layer. The methods outlined promote defect reduction through masking, annihilation and coalescence, therefore producing semiconductor structures with low defect densities. The invention can be applied to a wide range of semiconductor materials, both elemental semiconductors, e.g., combinations of Si (silicon) with strained Si (sSi) and/or Ge (germanium), and compound semiconductors, e.g., group II-VI and group III-V compound semiconductor materials. | 04-09-2009 |
20090115028 | METHOD FOR MANUFACTURING SEMICONDUCTOR SUBSTRATE, SEMICONDUCTOR DEVICE AND ELECTRONIC DEVICE - A semiconductor substrate including a single crystal semiconductor layer with a buffer layer interposed therebetween is manufactured. A semiconductor substrate is doped with hydrogen to form a damaged layer containing a large amount of hydrogen. After the single crystal semiconductor substrate and a supporting substrate are bonded, the semiconductor substrate is heated so that the single crystal semiconductor substrate is separated along a separation plane. The single crystal semiconductor layer is irradiated with a laser beam from the single crystal semiconductor layer side to melt a region in the depth direction from the surface of the laser-irradiated region of the single crystal semiconductor layer. Recrystallization progresses based on the plane orientation of the single crystal semiconductor layer which is solid without being melted; therefore, crystallinity of the single crystal semiconductor layer is recovered and the surface of the single crystal semiconductor layer is planarized. | 05-07-2009 |
20090121325 | METHOD FOR PRODUCING A THIN FILM TRANSISTOR AND A DEVICE OF THE SAME - A method for producing a thin film transistor and including the following steps for preparing a glass substrate; having a positive photosensitive coating on the glass substrate; providing a transparent mold plate, having a plurality of ladder opaque protrusions in accordance with a predetermined pattern having different depth; controlling the transparent mold plate downwardly to press into the positive photosensitive coating and non-contacting to the glass substrate; exploring a part of the positive photosensitive coating via an explosion by a UV light; remaining the other part of the positive photosensitive coating, which is shielded by the protrusions and shaped corresponding to the predetermined pattern; separating the transparent mold plate from the glass substrate, and removing the other parts of the photosensitive coating unshielded via a chemical solvent. Thereby, after the positive photosensitive coating is pressed, cured, and cleaned the thin film transistor is formed. | 05-14-2009 |
20090160033 | SEMICONDUCTOR OPTICAL ELEMENT - A light receiving element | 06-25-2009 |
20090160034 | MESA SEMICONDUCTOR DEVICE AND METHOD OF MANUFACTURING THE SAME - The invention provides a mesa semiconductor device and a method of manufacturing the same which minimize the manufacturing cost and prevents contamination and physical damage of the device. An N− type semiconductor layer is formed on a front surface of a semiconductor substrate, and a P type semiconductor layer is formed thereon. An anode electrode is further formed on the P type semiconductor layer so as to be connected to the P type semiconductor layer, and a mesa groove is formed from the front surface of the P type semiconductor layer deeper than the N− type semiconductor layer so as to surround the anode electrode. Then, a second insulation film is formed from inside the mesa groove onto the end portion of the anode electrode. The second insulation film is made of an organic insulator such as polyimide type resin or the like. The lamination body made of the semiconductor substrate and the layers laminated thereon is then diced along a scribe line. | 06-25-2009 |
20090160035 | MESA SEMICONDUCTOR DEVICE AND METHOD OF MANUFACTURING THE SAME - The invention provides a mesa semiconductor device and a method of manufacturing the same which enhance the yield and productivity. An N− type semiconductor layer is formed on a front surface of a semiconductor substrate, and a P type semiconductor layer is formed thereon. An anode electrode is further formed on the P type semiconductor layer so as to be connected to the P type semiconductor layer, and a mesa groove is formed from the front surface of the P type semiconductor layer deeper than the N− type semiconductor layer so as to surround the anode electrode. Then, a second insulation film is formed from inside the mesa groove onto the P type semiconductor layer on the outside of the mesa groove. The second insulation film is made of an organic insulator such as polyimide type resin or the like. The lamination body made of the semiconductor substrate and the layers laminated thereon is then diced along a scribe line. | 06-25-2009 |
20090267195 | SEMICONDUCTOR ELEMENT AND METHOD FOR MANUFACTURING SEMICONDUCTOR ELEMENT - A semiconductor device of present invention comprises a layered structure including a cladding layer with a first conductivity, an active layer, and a cladding layer with a second conductivity which are successively grown on a semiconductor substrate of (001) orientation, and an embedding layer covering both side surfaces of the layered structure in a widthwise direction across a longitudinal direction of the layered structure in a plane parallel to a surface of the semiconductor substrate. A portion of side surfaces of the active layer in the widthwise direction lies parallel to at least (010) or (100) surface. | 10-29-2009 |
20090309193 | MESA TYPE SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD THEREOF - Problems with a conventional mesa type semiconductor device, which are deterioration in a withstand voltage and occurrence of a leakage current caused by reduced thickness of an insulation film on an inner wall of a mesa groove corresponding to a PN junction, are solved using an inexpensive material, and a mesa type semiconductor device of high withstand voltage and high reliability is offered together with its manufacturing method. A stable protection film made of a thermal oxide film is formed on the inner wall of the mesa groove in the mesa type semiconductor device to cover and protect the PN junction, and an insulation film having negative electric charges is formed to fill a space in the mesa groove covered with the thermal oxide film so that an electron accumulation layer is not easily formed at an interface between an N | 12-17-2009 |
20090309194 | MESA TYPE SEMICONDUCTOR DEVICE AND MAUFACTURING METHOD THEREOF - This invention is directed to solving problems with a mesa type semiconductor device, which are deterioration in a withstand voltage and occurrence of a leakage current caused by reduced thickness of a second insulation film on an inner wall of a mesa groove corresponding to a PN junction, and offers a mesa type semiconductor device of high withstand voltage and high reliability and its manufacturing method. After the mesa groove is formed by dry-etching, wet-etching with an etching solution including hydrofluoric acid and nitric acid is further applied to a sidewall of the mesa groove to form an overhang made of the first insulation film above an upper portion of the mesa groove. The overhang serves as a barrier to prevent the second insulation film formed in the mesa groove and on the first insulation film around the mesa groove beyond an area of the overhang from flowing toward a bottom of the mesa groove due to an increased fluidity resulting from a subsequent thermal treatment. As a result, the inner wall of the mesa groove corresponding to the PN junction is covered with the second insulation film thick enough to secure a desired withstand voltage and to reduce a leakage current. | 12-17-2009 |
20100155906 | SEMICONDUCTOR DEVICE AND METHOD OF FORMING PATTERNS FOR THE SEMICONDUCTOR DEVICE - Provided are a method of forming patterns for a semiconductor device in which a pattern density is doubled by performing double patterning in a part of a device region while patterns having different widths are being simultaneously formed, and a semiconductor device having a structure to which the method is easily applicable. The semiconductor device includes a plurality of line patterns extending parallel to each other in a first direction. A plurality of first line patterns are alternately selected in a second direction from among the plurality of line patterns and each have a first end existing near the first side. A plurality of second line patterns are alternately selected in the second direction from among the plurality of line patterns and each having a second end existing near the first side. The first line patterns alternate with the second line patterns and the first end of each first line pattern is farther from the first side than the second end of each second line pattern. | 06-24-2010 |
20100181651 | SEALED SEMICONDUCTOR DEVICE - A sealed semiconductor device having reduced delamination of the sealing layer in high temperature, high humidity conditions is disclosed. The semiconductor device includes a substrate and a stack of device layers on the substrate sealed with a sealing layer. The upper surface of a street area of the substrate is oxidized so that the oxidized region extends under the sealing layer. The presence of the oxidized region of the upper surface of the substrate helps reduce the delamination, because the oxidized surface does not react with water to the same extent as a non-oxidized surface. The semiconductor devices remain sealed after dicing through the street area because the oxidized surface does not delaminate. | 07-22-2010 |
20100213579 | METHODS FOR FABRICATION OF HIGH ASPECT RATIO MICROPILLARS AND NANOPILLARS - Methods for fabrication of high aspect ratio micropillars and nanopillars are described. Use of alumina as an etch mask for the fabrication methods is also described. The resulting micropillars and nanopillars are analyzed and a characterization of the etch mask is provided. | 08-26-2010 |
20100308445 | SEMICONDUCTOR DEVICE AND METHOD OF MANUFACTURING SEMICONDUCTOR DEVICE - A semiconductor device includes a semiconductor layer stacked on a substrate, a stripe-shaped ridge formed on a surface of the semiconductor layer, and electrode formed on an upper surface of the ridge and a protective film disposed on each side of the ridge. The electrode includes a flat portion having a flat surface substantially parallel to the upper surface of the ridge and sloped portions on both sides of the flat portion with each of the sloped portions having a sloped surface that is sloped with respect to the upper surface of the ridge. The protective film covers a region from a side surface of the ridge to the sloped surface of the sloped portion of the electrode. | 12-09-2010 |
20110108961 | DEVICE HAVING AND METHOD FOR FORMING FINS WITH MULTIPLE WIDTHS - A method for fabrication of features for an integrated circuit includes patterning a mandrel layer to include structures having at least one width on a surface of an integrated circuit device. Exposed sidewalls of the structures are reacted to integrally form a new compound in the sidewalls such that the new compound extends into the exposed sidewalls by a controlled amount to form pillars. One or more layers below the pillars are etched using the pillars as an etch mask to form features for an integrated circuit device. | 05-12-2011 |
20110180910 | VERTICAL SEMICONDUCTOR DEVICE AND METHOD OF MANUFACTURING THE SAME - A vertical semiconductor device with improved junction profile and a method of manufacturing the same are provided. The vertical semiconductor device includes a pillar vertically extended from a surface of a semiconductor substrate, a silicon layer formed in a bit line contact region of one sidewall of the pillar, and a junction region formed within a portion of the pillar contacting with the silicon layer. | 07-28-2011 |
20110180911 | METHODS FOR RELAXATION AND TRANSFER OF STRAINED LAYERS AND STRUCTURES FABRICATED THEREBY - The present invention provides methods for forming at least partially relaxed strained material layers on a target substrate. The methods include forming islands of the strained material layer on an intermediate substrate, at least partially relaxing the strained material islands by a first heat treatment, and transferring the at least partially relaxed strained material islands to the target substrate. The at least partial relaxation is facilitated by the presence of low-viscosity or compliant layers adjacent to the strained material layer. The invention also provides semiconductor structures having an at least partially relaxed strained material layer, and semiconductor devices fabricated using an at least partially relaxed strained material layer. | 07-28-2011 |
20110272791 | METHOD FOR FORMING SEMICONDUCTOR DEVICES WITH ACTIVE SILICON HEIGHT VARIATION - A method far farming different active thicknesses on the same silicon layer includes masking the silicon layer and exposing selected regions of the silicon layer. The thickness of the silicon layer at the exposed regions is changed, either by adding silicon or subtracting silicon from the layer at the exposed regions. Once the mask is removed, the silicon layer has regions of different active thicknesses, respectively suitable for use in different types of devices, such as diodes and transistors. | 11-10-2011 |
20110291247 | RELAXATION AND TRANSFER OF STRAINED MATERIAL LAYERS - The present invention relates to a method for the formation of an at least partially relaxed strained material layer, the method comprising the steps of providing a seed substrate; patterning the seed substrate; growing a strained material layer on the patterned seed substrate; transferring the strained material layer from the patterned seed substrate to an intermediate substrate; and at least partially relaxing the strained material layer by a heat treatment. | 12-01-2011 |
20110298098 | EXPITAXIAL FABRICATION OF FINS FOR FINFET DEVICES - A fin for a finFET is described. The fin is a portion of a layer of material, where, another portion of the layer of material resides on a sidewall. | 12-08-2011 |
20110304028 | SEMICONDUCTOR DEVICE AND METHOD OF MANUFACTURING THE SAME - A semiconductor device which forms a barrier layer formed of a doped polysilicon layer on a buried bit line to prevent the bit line conductive layer from being exposed during the etching process for forming a buried word line, thereby improving characteristics of the device, and a method of manufacturing the same, are provided. The semiconductor device includes a first pillar pattern and a second pillar pattern, including sidewall contacts, and a buried bit line including a bit line conductive layer disposed over a lower part of a trench between the first pillar pattern and the second pillar pattern, and a barrier layer stacked over the bit line conductive layer. | 12-15-2011 |
20120001303 | SEMICONDUCTOR STRUCTURE HAVING LOW THERMAL STRESS AND METHOD FOR MANUFACTURING THEREOF - A semiconductor structure includes a Si substrate, a supporting layer and a blocking layer formed on the substrate and an epitaxy layer formed on the supporting layer. The supporting layer defines a plurality of grooves therein to receive the blocking layer. The epitaxy layer is grown from the supporting layer. A plurality of slots is defined in the epitaxy layer and over the blocking layer. The epitaxy layer includes an N-type semiconductor layer, a light-emitting layer and a P-type semiconductor layer. A method for manufacturing the semiconductor structure is also disclosed. | 01-05-2012 |
20120038032 | FLEXIBLE DEVICE AND METHOD OF MANUFACTURING THE SAME - The rollable device of the invention comprises a substrate of an insulating material with apertures extending from a first to a second side. On the first side switching elements are present, as well as interconnect lines and the like, covered by a coating of organic material. On the second side a functional layer is present. Examples of such functional layers include capacitors, antennas and particularly electro-optical layers. Thus, with a rollable display that may include an antenna and a driver circuit is obtained. | 02-16-2012 |
20120126375 | METHOD FOR FORMING METROLOGY STRUCTURES FROM FINS IN INTEGRATED CIRCUITRY - A method for forming a plurality of fins on a semiconductor substrate includes depositing a spacer layer to fill in gaps between the plurality of fins, the fins comprising a first material and the spacer layer comprising a second material. A first area is defined where the fins need to be broadened and a second area is defined where the fins do not need to be broadened. The method also includes patterning the spacer layer to remove spacers in the first area where the fins need to be broadened and applying an epitaxy process at a predetermined rate to grow a layer of the first material on fins in the first area. The spacer layer is removed in the second area where the fins do not need broadening. | 05-24-2012 |
20120175749 | Structure and Method to Fabricate Resistor on FinFET Processes - A structure comprises first and at least second fin structures are formed. Each of the first and at least second fin structures has a vertically oriented semiconductor body. The vertically oriented semiconductor body is comprised of vertical surfaces. A doped region in each of the first and at least second fin structures is comprised of a concentration of dopant ions present in the semiconductor body to form a first resistor and at least a second resistor, and a pair of merged fins formed on outer portions of the doped regions of the first and at least second fin structures. The pair of merged fins is electrically connected so that the first and at least second resistors are electrically connected in parallel with each other. | 07-12-2012 |
20120241918 | PROCESS FOR THE REALIZATION OF ISLANDS OF AT LEAST PARTIALLY RELAXED STRAINED MATERIAL - The present invention relates to the field of semiconductor manufacturing. More specifically, it relates to a method of forming islands of at least partially relaxed strained material on a target substrate including the steps of forming islands of the strained material over a side of a first substrate; bonding the first substrate, on the side including the islands of the strained material, to the target substrate; and after the step of bonding splitting the first substrate from the target substrate and at least partially relaxing the islands of the strained material by a first heat treatment. | 09-27-2012 |
20120241919 | METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE, AND SEMICONDUCTOR DEVICE - The present invention provides a method for selectively transferring elements such as monocrystalline Si thin films or elements made of monocrystalline Si from a base substrate ( | 09-27-2012 |
20120256302 | METHOD FOR PRODUCING A THIN FILM TRANSISTOR AND A DEVICE OF THE SAME - A method for producing a thin film transistor and including the following steps for preparing a glass substrate; having a positive photosensitive coating on the glass substrate; providing a transparent mold plate, having a plurality of ladder opaque protrusions in accordance with a predetermined pattern having different depth; controlling the transparent mold plate downwardly to press into the positive photosensitive coating and non-contacting to the glass substrate; exposing a part of the positive photosensitive coating via an explosion by a UV light; remaining the other part of the positive photosensitive coating, which is shielded by the protrusions and shaped corresponding to the predetermined pattern; separating the transparent mold plate from the glass substrate, and removing the other parts of the photosensitive coating unshielded via a chemical solvent. Thereby, after the positive photosensitive coating is pressed, cured, and cleaned the thin film transistor is formed. | 10-11-2012 |
20120286402 | PROTUBERANT STRUCTURE AND METHOD FOR MAKING THE SAME - A cuboidal protuberant structure is provided. The cuboidal protuberant structure includes a substrate and a protrusion disposed on the substrate. The protrusion has a vertical side wall with a rounded corner, a protuberant width and a protuberant length. At least one of the protuberant width and the protuberant length is not greater than 33 nm. | 11-15-2012 |
20130001753 | TEMPLATE SUBSTRATE AND METHOD FOR MANUFACTURING SAME - According to one embodiment, a template substrate includes a substrate and a mask. The substrate includes a mesa region formed in a central portion of an upper surface of the substrate. The mesa region is configured to protrude more than a region of the substrate around the mesa region. An impurity is introduced into an upper layer portion of a partial region of a peripheral portion of the mesa region. The mask film is provided on the upper surface of the substrate. | 01-03-2013 |
20130099361 | Semiconductor Structure and Method for Manufacturing the Same - The present invention provides a method for manufacturing a semiconductor structure, comprising the steps of: providing a semiconductor substrate, forming an insulating layer on the semiconductor substrate, and forming a semiconductor base layer on the insulating layer; forming a sacrificial layer and a spacer surrounding the sacrificial layer on the semiconductor base layer, and etching the semiconductor base layer by taking the spacer as a mask to form a semiconductor body; forming an insulating film on sidewalls of the semiconductor body; removing the sacrificial layer and the semiconductor body located under the sacrificial layer to form a first semiconductor fin and a second semiconductor fin. Correspondingly, the present invention further provides a semiconductor structure. In the present invention, an oxide film is formed on the sidewalls of the two semiconductor fins that are far away from each other, while only the sidewalls of the two semiconductor fins that are opposite to each other are exposed, such that conventional operations may be easily performed to the sidewalls opposite to each other in the subsequent process. | 04-25-2013 |
20130099362 | METHOD OF FORMING SELF-ASSEMBLED PATTERNS USING BLOCK COPOLYMERS, AND ARTICLES THEREOF - A method of forming a block copolymer pattern comprises providing a substrate comprising a topographic pre-pattern comprising a ridge surface separated by a height, h, greater than 0 nanometers from a trench surface; disposing a block copolymer comprising two or more block components on the topographic pre-pattern to form a layer having a thickness of more than 0 nanometers over the ridge surface and the trench surface; and annealing the layer to form a block copolymer pattern having a periodicity of the topographic pre-pattern, the block copolymer pattern comprising microdomains of self-assembled block copolymer disposed on the ridge surface and the trench surface, wherein the microdomains disposed on the ridge surface have a different orientation compared to the microdomains disposed on the trench surface. Also disclosed are semiconductor devices. | 04-25-2013 |
20130127020 | MICRO DEVICE TRANSFER HEAD - A micro device transfer head and head array are disclosed. In an embodiment, the micro device transfer head includes a base substrate, a mesa structure with sidewalls, an electrode formed over the mesa structure, and a dielectric layer covering the electrode. A voltage can be applied to the micro device transfer head and head array to pick up a micro device from a carrier substrate and release the micro device onto a receiving substrate. | 05-23-2013 |
20130214393 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD THEREOF - An object is to provide a semiconductor device with improved reliability in which a defect stemming from an end portion of a semiconductor layer provided in an island shape is prevented, and a manufacturing method thereof. Over a substrate having an insulating surface, an island-shaped semiconductor layer is formed, a first alteration treatment is performed, a first insulating film is formed on a surface of the island-shaped semiconductor layer, the first insulating film is removed, a second alteration treatment is performed on the island-shaped semiconductor from which the first insulating film is removed, a second insulating film is formed on a surface of the island-shaped semiconductor layer, and a conductive layer is formed over the second insulating film. An upper end portion of the island-shaped semiconductor layer has curvature by the first alteration treatment and the second alteration treatment. | 08-22-2013 |
20130234297 | SEMICONDUCTOR DEVICE, WAFER ASSEMBLY AND METHODS OF MANUFACTURING WAFER ASSEMBLIES AND SEMICONDUCTOR DEVICES - A cavity is formed in a working surface of a substrate in which a semiconductor element is formed. A glass piece formed from a glass material is bonded to the substrate, and the cavity is filled with the glass material. For example, a pre-patterned glass piece is used which includes a protrusion fitting into the cavity. Cavities with widths of more than 10 micrometers are filled fast and reliably. The cavities may have inclined sidewalls. | 09-12-2013 |
20130241038 | STRUCTURE AND METHOD FOR CREATING A REUSABLE TEMPLATE FOR DETACHABLE THIN FILM SUBSTRATES - A structure and method operable to create a reusable template for detachable thin semiconductor substrates is provided. The template has a shape such that the 3-D shape is substantially retained after each substrate release. Prior art reusable templates may have a tendency to change shape after each subsequent reuse; the present disclosure aims to address this and other deficiencies from the prior art, therefore increasing the reuse life of the template. | 09-19-2013 |
20130285215 | STACKED WAFER STRUCTURE AND METHOD FOR STACKING A WAFER - A stacked wafer structure includes a substrate; dams provided on the substrate and having protrusions on a surface thereof; and a wafer with recesses provided on the dam. The protrusions on the surface of the dams are wedged into the recesses of the wafer, preventing air chambers from forming between the recesses of the wafer and the dams, so that the wafer is not separated from the dams due to the presence of air chambers during subsequent packaging process. A method for stacking a wafer is also provided. | 10-31-2013 |
20130285216 | SEMICONDUCTOR STRUCTURE HAVING LOW THERMAL STRESS - A semiconductor structure includes a Si substrate, a supporting layer and a blocking layer formed on the substrate and an epitaxy layer formed on the supporting layer. The supporting layer defines a plurality of grooves therein to receive the blocking layer. The epitaxy layer is grown from the supporting layer. A plurality of slots is defined in the epitaxy layer and over the blocking layer. The epitaxy layer includes an N-type semiconductor layer, a light-emitting layer and a P-type semiconductor layer. | 10-31-2013 |
20130299951 | FIN STRUCTURE - Provided is a fin structure including a fin and two insulating layers. The fin is disposed on a substrate, wherein an upper portion is narrower than a lower portion of the fin, and the fin has an inverse T shape. The insulating layers are disposed at two sides of the fin and at least expose the upper portion of the fin. | 11-14-2013 |
20130307125 | CHIP PACKAGE AND METHOD FOR FORMING THE SAME - An embodiment of the invention provides a chip package which includes: a semiconductor substrate having an upper surface and a lower surface; a device region or sensing region defined in the semiconductor substrate; a conducting pad located on the upper surface of the semiconductor substrate; at least two recesses extending from the upper surface towards the lower surface of the semiconductor substrate, wherein sidewalls and bottoms of the recesses together form a sidewall of the semiconductor substrate; a conducting layer electrically connected to the conducting pad and extending from the upper surface of the semiconductor substrate to the sidewall of the semiconductor substrate; and an insulating layer located between the conducting layer and the semiconductor substrate. | 11-21-2013 |
20140021588 | SEMICONDUCTOR DEVICE AND PRODUCTION METHOD - The object to provide a semiconductor device comprising a highly-integrated SGT-based CMOS inverter circuit is achieved by forming an inverter which comprises: a first transistor including; an first island-shaped semiconductor layer; a first gate insulating film; a gate electrode; a first first-conductive-type high-concentration semiconductor layer arranged above the first island-shaped semiconductor layer; and a second first-conductive-type high-concentration semiconductor layer arranged below the first island-shaped semiconductor layer, and a second transistor including; a second gate insulating film surrounding a part of the periphery of the gate electrode; a second semiconductor layer in contact with a part of the periphery of the second gate insulating film; a first second-conductive-type high-concentration semiconductor layer arranged above the second semiconductor layer; and a second second-conductive-type high-concentration semiconductor layer arranged below the second semiconductor layer. | 01-23-2014 |
20140042596 | BONDED WAFER STRUCTURES - The present disclosure includes bonded wafer structures and methods of forming bonded wafer structures. One example of a forming a bonded wafer structure includes providing a first wafer ( | 02-13-2014 |
20140054753 | NANO-MESHED STRUCTURE PATTERN ON SAPPHIRE SUBSTRATE BY METAL SELF-ARRANGEMENT - The present disclosure provides a nano-meshed patterned substrate and a method of forming the same. In an embodiment, a metal layer is formed on a substrate, and a heat treatment is performed on the substrate and the metal layer so that the metal layer is transformed into a nano-meshed metal structure. The substrate is then etched using the nano-meshed metal structure as an etch mask. After removing the nano-meshed metal structure, a nano-meshed patterned substrate is obtained. | 02-27-2014 |
20140097522 | METHODS AND APPARATUS FOR IDENTIFYING AND REDUCING SEMICONDUCTOR FAILURES - The present disclosure provides multi-junction solar cell structures and fabrication methods thereof that improve electrical testing capability and reduce chip failure rates. In the present invention a special masking pattern is used in the layout such that all or some of the epitaxial layers are etched away in the corner areas of each solar cell. Consequently, the semiconductor substrate or one or more of the interconnections between junctions become accessible from the top (the side facing the sun) to make electrical connections. | 04-10-2014 |
20140239460 | Semiconductor Device Having an Insulating Layer Structure and Method of Manufacturing the Same - In a semiconductor device having an insulating layer structure and method of manufacturing the same, a substrate including a first region and a second region may be provided. A first pattern structure may be formed on the first region of the substrate. A second pattern structure may be formed on the second region of the substrate, and have a height that is greater than the height of the first pattern structure. An insulating layer structure is formed on the first and second pattern structures and includes a protrusion near an area at which the first and second regions meet each other. An upper surface of the insulating interlayer structure is higher than a top surface of the second pattern structure. The protrusion may have at least one side surface having a staircase shape. A planarized insulating interlayer may be formed without substantial damage to the infrastructure by using the insulating layer structure in accordance with example embodiments. | 08-28-2014 |
20140264775 | METHOD AND SYSTEM FOR TRANSIENT VOLTAGE SUPPRESSION - A transient voltage suppression (TVS) device and a method of forming the device are provided. The device includes a first layer of wide band gap semiconductor material formed of a first conductivity type material, a second layer of wide band gap semiconductor material formed of a second conductivity type material over at least a portion of the first layer and comprising an ion implanted material structure between 0.1 micrometers (μm) and 22.0 μm thick, the second layer operating using punch-through physics, and a third layer of wide band gap semiconductor material formed of the first conductivity type material over at least a portion of the second layer. | 09-18-2014 |
20140299972 | SEMICONDUCTOR DEVICE HAVING A THROUGH CONTACT - A semiconductor device includes a semiconductor substrate having a first side and a second side opposite the first side, an active area and a through contact area, the active area including a transistor structure having a control electrode, the through contact area including a semiconductor mesa having insulated sidewalls. The semiconductor device further includes a first metallization on the first side in the active area and a recess extending from the first side into the semiconductor substrate and between the active area and the through contact area and including in the through contact area a horizontally widening portion, the recess being at least partly filled with a conductive material forming a first conductive region in ohmic contact with the semiconductor mesa and the transistor structure. The semiconductor device also includes a control metallization on the second side and in ohmic contact with the semiconductor mesa. | 10-09-2014 |
20140299973 | Multilayer line trimming - Substantially simultaneous plasma etching of polysilicon and oxide layers in multilayer lines in semiconductors allows for enhanced critical dimensions and aspect ratios of the multilayer lines. Increasing multilayer line aspect ratios may be possible, allowing for increased efficiency, greater storage capacity, and smaller critical dimensions in semiconductor technologies. | 10-09-2014 |
20140306323 | Semiconductor Constructions - Some embodiments include semiconductor constructions having semiconductor material patterned into two mesas spaced from one another by at least one dummy projection. The dummy projection has a width along a cross-section of X and the mesas have widths along the cross-section of at least 3X. Some embodiments include semiconductor constructions having a memory array region and a peripheral region adjacent the memory array region. Semiconductor material within the peripheral region is patterned into two relatively wide mesas spaced from one another by at least one relatively narrow projection. The relatively narrow projection has a width along a cross-section of X and the relatively wide mesas have widths along the cross-section of at least 3X. | 10-16-2014 |
20140332933 | SEMICONDUCTOR STRUCTURE AND METHOD FOR FORMING THE SAME - A semiconductor structure and a method for forming the same are provided. The semiconductor structure comprises: a substrate; and a plurality of convex structures formed on a surface of the substrate and arranged in a longitudinal direction of the substrate, each convex structure having a top surface, a bottom surface located on the surface of the substrate, a first end surface and a second end surface parallel to each other, and a front side surface and a rear side surface parallel to each other, in which the rear side surface of one of two adjacent convex structures and the front side surface of the other are located on a same plane to allow the plurality of convex structures to form a zigzag structure. | 11-13-2014 |
20150028455 | METHOD FOR VARIED TOPOGRAPHIC MEMS CAP PROCESS - A device includes sidewalls formed in a wafer surface, where the sidewalls descend to a recessed surface. The recessed surface generally promotes resist coverage on the wafer surface, including corners (e.g., junctions between the wafer surface and various surface topographies, such as cavities, the recessed surface, and so forth) on the wafer. In one or more implementations, a wet etching procedure is used to form the sidewalls and recessed surface. A resist material (e.g., a photoresist material) is deposited onto the wafer surface, where the photoresist fully covers one or more of the top corners of the wafer surface. In one or more implementations, the recessed surface is positioned adjacent a trench formed in the wafer to promote resist coverage on the top surface of the wafer. | 01-29-2015 |
20150041962 | Semiconductor Device with Cell Trench Structures and Contacts and Method of Manufacturing a Semiconductor Device - First and second cell trench structures extend from a first surface into a semiconductor substrate. The first cell trench structure includes a first buried electrode and a first insulator layer between the first buried electrode and a semiconductor mesa separating the first and second cell trench structures. A capping layer covers the first surface. The capping layer is patterned to form an opening having a minimum width larger than a thickness of the first insulator layer. The opening exposes a first vertical section of the first insulator layer at the first surface. An exposed portion of the first insulator layer is removed to form a recess between the semiconductor mesa and the first buried electrode. A contact structure is in the opening and the recess. The contact structure electrically connects both a buried zone in the semiconductor mesa and the first buried electrode and allows for narrower semiconductor mesa width. | 02-12-2015 |
20150061086 | THREE-DIMENSIONAL SEMICONDUCTOR TEMPLATE FOR MAKING HIGH EFFICIENCY THIN-FILM SOLAR CELLS - A semiconductor template having a top surface aligned along a (100) crystallographic orientation plane and an inverted pyramidal cavity defined by a plurality of walls aligned along a (111) crystallographic orientation plane. A method for manufacturing a semiconductor template by selectively removing silicon material from a silicon template to form a top surface aligned along a (100) crystallographic plane of the silicon template and a plurality of walls defining an inverted pyramidal cavity each aligned along a (111) crystallographic plane of the silicon template. | 03-05-2015 |
20150076668 | CONDUCTOR WITH A PLURALITY OF VERTICAL EXTENSIONS FOR A 3D DEVICE - Conductors in a 3D circuit that include horizontal lines with a plurality of vertical extensions in high aspect ratio trenches can be formed using a two-step etching procedure. The procedure can comprise providing a substrate having a plurality of spaced-apart stacks; forming a pattern of vertical pillars in a body of conductor material between stacks; and forming a pattern of horizontal lines in the body of conductor material over stacks, the horizontal lines connecting vertical pillars in the pattern of vertical pillars. The body of conductor material can be deposited over the plurality of spaced-apart stacks. A first etch process can be used to form the pattern of vertical pillars. A second etch process can be used to form the pattern of horizontal lines. The conductors can be used as word lines or as bit lines in 3D memory. | 03-19-2015 |
20150097275 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD OF SEMICONDUCTOR DEVICE - A semiconductor device includes a substrate, a substrate-side electrode layer, an intermediate electrode layer, and a front-side electrode layer. The substrate includes a semiconductor layer and a projection portion, the projection portion being formed on a surface of the semiconductor layer. The substrate-side electrode layer is provided on the projection portion. The intermediate electrode layer extends from on a part of the substrate-side electrode layer, which part of the substrate-side electrode layer is located on the projection portion, to just above a region of the substrate in which region the projection portion is not provided. The front-side electrode layer is provided on a surface of the intermediate electrode layer. A Young's modulus E1 of the substrate-side electrode layer, a Young's modulus E2 of the intermediate electrode layer, and a Young's modulus E3 of the front-side electrode layer satisfy a relationship of E3>E1>E2. | 04-09-2015 |
20150108615 | TECHNIQUE FOR CONTROLLING POSITIONS OF STACKED DIES - An assembly component and a technique for assembling a chip package using the assembly component are described. This chip package includes a set of semiconductor dies that are arranged in a stack in a vertical direction, which are offset from each other in a horizontal direction to define a stepped terrace at one side of the vertical stack. Moreover, the chip package may be assembled using the assembly component. In particular, the assembly component may include a pair of stepped terraces that approximately mirror the stepped terrace of the chip package and which provide vertical position references for an assembly tool that positions the set of semiconductor dies in the vertical stack during assembly of the chip package. | 04-23-2015 |
20150108616 | MULTI-HEIGHT MULTI-COMPOSITION SEMICONDUCTOR FINS - A dielectric material layer is formed on a semiconductor-on-insulator (SOI) substrate including a top semiconductor layer containing a first semiconductor material. An opening is formed within the dielectric material layer, and a trench is formed in the top semiconductor layer within the area of the opening by an etch. A second semiconductor material is deposited to a height above the top surface of the top semiconductor layer employing a selective epitaxy process. Another dielectric material layer can be deposited, and another trench can be formed in the top semiconductor layer. Another semiconductor material can be deposited to a different height employing another selective epitaxy process. The various semiconductor material portions can be patterned to form semiconductor fins having different heights and/or different compositions. | 04-23-2015 |
20150137332 | CARRIER FOR A SEMICONDUCTOR LAYER - A carrier for carrying a semiconductor layer having a growth surface and at least one nano-patterned structure on the growth surface is provided. The at least one nano-patterned structure on the growth surface of the carrier has a plurality of mesas, a recess is formed between two adjacent mesas, in which a depth of the recess ranges from 10 nm to 500 nm, and a dimension of the mesa ranges from 10 nm to 800 nm. | 05-21-2015 |
20150311284 | SPATIAL SEMICONDUCTOR STRUCTURE - A method of fabricating a spatial semiconductor structure includes steps as follows. Firstly, a semiconductor substrate is provided. Then, a first mask layer is formed above the semiconductor substrate. Then, at least a first opening is formed in the first mask layer and exposes a portion of a surface of the semiconductor substrate. Then, a first semiconductor pattern is formed in the first opening. Then, a second mask layer is formed over the first semiconductor pattern and the first mask layer. Then, at least a second opening is formed through the second mask layer to the first mask layer and exposes another portion of the surface of the semiconductor substrate. And, a second semiconductor pattern is formed in the second opening. | 10-29-2015 |
20150333156 | DIELECTRIC FILLER FINS FOR PLANAR TOPOGRAPHY IN GATE LEVEL - An array of stacks containing a semiconductor fins and an oxygen-impermeable cap is formed on a semiconductor substrate with a substantially uniform areal density. Oxygen-impermeable spacers are formed around each stack, and the semiconductor substrate is etched to vertically extend trenches. Semiconductor sidewalls are physically exposed from underneath the oxygen-impermeable spacers. The oxygen-impermeable spacers are removed in regions in which semiconductor fins are not needed. A dielectric oxide material is deposited to fill the trenches. Oxidation is performed to convert a top portion of the semiconductor substrate and semiconductor fins not protected by oxygen-impermeable spacers into dielectric material portions. Upon removal of the oxygen-impermeable caps and remaining oxygen-impermeable spacers, an array including semiconductor fins and dielectric fins is provided. The dielectric fins alleviate variations in the local density of protruding structures, thereby reducing topographical variations in the height of gate level structures to be subsequently formed. | 11-19-2015 |
20150340364 | COMPLEX CIRCUITS UTILIZING FIN STRUCTURES - A method of forming a semiconductor structure includes forming a multilayer lattice matched structure having an unstrained layer, a first strained layer, and a second strained layer formed between the unstrained and the first strained layer. A first opening in the multilayer structure is etched and a second strained fill material having a same material as the second strained layer is deposited. A second opening in the multilayer structure is etched and an unstrained fill material having a same material as the unstrained layer is deposited. A first strained fill material having a same material as the first strained layer is then deposited between the unstrained fill and the second strained fill. A second strained fin is formed from the deposited second strained fill material, a first strained fin is formed from the deposited first strained fill material, and an unstrained fin is formed from the deposited unstrained fill material. | 11-26-2015 |
20150349054 | DOUBLE/MULTIPLE FIN STRUCTURE FOR FINFET DEVICES - A method of forming double and/or multiple numbers of fins of a FinFET device using a Si/SiGe selective epitaxial growth process and the resulting device are provided. Embodiments include forming a Si pillar in an oxide layer, the Si pillar having a bottom portion and a top portion; removing the top portion of the Si pillar; forming a SiGe pillar on the bottom portion of the Si pillar; reducing the SiGe pillar; forming a first set of Si fins on opposite sides of the reduced SiGe pillar; removing the SiGe pillar; replacing the Si fins with SiGe fins; reducing the SiGe fins; forming a second set of Si fins on opposite sides of the SiGe fins; and removing the SiGe fins. | 12-03-2015 |
20150357190 | SEMICONDUCTOR DEVICE HAVING FIN-SHAPED STRUCTURE AND METHOD FOR FABRICATING THE SAME - A semiconductor device with fin-shaped structure is disclosed. The semiconductor device includes: a substrate; a fin-shaped structure on the substrate; and an epitaxial layer on a top surface and part of the sidewall of the fin-shaped structure, in which the epitaxial layer and the fin-shaped structure includes a linear gradient of germanium concentration therebetween. | 12-10-2015 |
20150364424 | COMPLIANT ELECTROSTATIC TRANSFER HEAD WITH SPRING SUPPORT LAYER - A compliant electrostatic transfer head and method of forming a compliant electrostatic transfer head are described. In an embodiment, a compliant electrostatic transfer head includes a cavity in a base substrate, a spring support layer on the base substrate, and a patterned device layer on the spring support layer. The spring support layer includes a spring support layer beam profile that extends over and is deflectable toward the cavity, and the patterned device layer includes an electrode beam profile that is supported by the spring support layer beam profile and extends over and is deflectable toward the cavity. | 12-17-2015 |
20160056045 | FIN STRUCTURE AND METHOD OF FORMING THE SAME - A fin structure and a method of forming the same, where the fin structure includes a fin and a protrusion having irregular shape. The fin and the protrusion are both formed on a substrate, and the protrusion has a height less than that of the fin. With such arrangement, the fin structure of the present invention, as well as the method of forming the same, can achieve the purpose of keeping the fin from collapsing and over etching. | 02-25-2016 |
20160093502 | FIN CUT FOR TIGHT FIN PITCH BY TWO DIFFERENT SIT HARD MASK MATERIALS ON FIN - Methods that enable fin cut at very tight pitch are provided. After forming a first set of paired sidewall image transfer (SIT) spacers and a second set of paired SIT spacers composed of different materials, portions of the first set of the paired SIT spacers can be selectively removed without adversely affecting the second set of the paired SIT spacers, even portions of both sets of the paired SIT spacers are exposed by the cut mask due to the different etching characteristics of the different materials. | 03-31-2016 |
20160099312 | NANOWIRE FABRICATION METHOD AND STRUCTURE THEREOF - A method of providing an out-of-plane semiconductor structure and a structure fabricated thereby is disclosed. The method comprises acts of: providing a substrate defining a major surface; providing a template layer having a predetermined template thickness on the major surface of the substrate; forming a recess in the template layer having a recess pattern and a recess depth smaller than the template thickness; and epitaxilally growing a semiconductor structure from the recess. A planar shape of the recess pattern formed in the template layer substantially dictates an extending direction of the semiconductor structure. | 04-07-2016 |
20160099313 | SEMICONDUCTOR STRUCTURE FOR A TRANSISTOR AND METHOD FOR FABRICATING THE SAME - A semiconductor structure includes a substrate and a fin. The fin extends from the substrate and is formed with a hole therethrough. The hole is defined by a confronting pair of wall parts. One of the wall parts is more arcuate than the other of the wall parts. A method for fabricating the semiconductor structure is also disclosed. | 04-07-2016 |
20160141185 | THIN-FILM PATTERN ARRAY AND PRODUCTION METHOD THEREFOR - Disclosed are: a thin-film pattern array able to minimize level differences between thin films; and a production method therefor. The thin-film pattern array comprises: a lower thin-film pattern which is positioned on a substrate; an upper thin-film pattern which is positioned on the upper edge of the lower thin-film pattern; and a level-difference attenuating pattern which is positioned between the lower thin-film pattern and the upper thin-film pattern, and has a gentle taper angle so as to be able to reduce the level difference between the lower thin-film pattern and the upper thin-film pattern. | 05-19-2016 |
20160254205 | DEVICE AND METHOD FOR LOCALIZED UNDERFILL | 09-01-2016 |
20170236722 | FIN FORMATION FOR SEMICONDUCTOR DEVICE | 08-17-2017 |
257625000 | Semiconductor body including mesa is intimately bonded to thick electrical and/or thermal conductor member of larger lateral extent than semiconductor body (e.g., "plated heat sink" microwave diode) | 1 |
20100052112 | Printable, Flexible and Stretchable Diamond for Thermal Management - Various heat-sinked components and methods of making heat-sinked components are disclosed where diamond in thermal contact with one or more heat-generating components are capable of dissipating heat, thereby providing thermally-regulated components. Thermally conductive diamond is provided in patterns capable of providing efficient and maximum heat transfer away from components that may be susceptible to damage by elevated temperatures. The devices and methods are used to cool flexible electronics, integrated circuits and other complex electronics that tend to generate significant heat. Also provided are methods of making printable diamond patterns that can be used in a range of devices and device components. | 03-04-2010 |
257626000 | Combined with passivating coating | 4 |
20080251891 | Semiconductor having passivated sidewalls - The layers of a semiconductor device have exposed edges. The layers that are susceptible to oxidation are protected from oxidation by coating them with a nitride passivation layer. The nitride passivation layer can be applied using plasma enhanced chemical vapor deposition (PECVD). A method of making a passivated sidewall semiconductor includes the steps of applying a nitride or other protective material over a wafer using PECVD or other appropriate deposition method. | 10-16-2008 |
20090102023 | Method for Manufacturing a Structure, Semiconductor Device and Structure on a Substrate - One possible embodiment is a method for manufacturing a structure on a substrate which can be used in the manufacturing of a semiconductor device, including the steps of: forming a first structure on the substrate having at least one sidewall, forming at least one layer as a second structure selectively on the at least one sidewall of the first structure by an epitaxial technique, electroplating, selective silicon dioxide deposition, selective low pressure CVD or an atomic layer deposition technique. Furthermore semiconductor devices, uses of equipment and structures are covered. | 04-23-2009 |
20090189257 | MESA TYPE SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD THEREOF - A mesa type semiconductor device and its manufacturing method are offered to increase a withstand voltage as well as reducing a leakage current. An N | 07-30-2009 |
20130207243 | Method of Manufacturing a Semiconductor Device - The method includes providing a semiconductor chip having a first main face and a second main face opposite the first main face. The semiconductor chip includes an electrical device adjacent to the first main face. Material of the semiconductor chip is removed at the second main face except for a pre-defined portion so that a non-planar surface remains at the second main face. | 08-15-2013 |