| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 438481000 | Utilizing epitaxial lateral overgrowth | 34 |
| 20080286949 | Method of Forming a Rare-Earth Dielectric Layer - Methods for forming compositions comprising a single-phase rare-earth dielectric disposed on a substrate are disclosed. In some embodiments, the method forms a semiconductor-on-insulator structure. Compositions and structures that are formed via the method provide the basis for forming high-performance devices and circuits. | 11-20-2008 |
| 20090004833 | METHOD OF MANUFACTURING SEMICONDUCTOR STORAGE DEVICE - A method of manufacturing a semiconductor storage device includes providing an opening portion in a plurality of positions in an insulating film formed on a silicon substrate, and thereafter forming an amorphous silicon film on the insulating film, in which the opening portions are formed, and in the opening portions. Then, trenches are formed to divide the amorphous silicon film, in the vicinity of a midpoint between adjacent opening portions, into a portion on one opening portion side and a portion on the other opening portion side. Next, the amorphous silicon film, in which the trenches are formed, is annealed and subjected to solid-phase crystallization to form a single crystal with the opening portions used as seeds, and thereby a silicon single-crystal layer is formed. Then, a memory cell array is formed on the silicon single-crystal layer. | 01-01-2009 |
| 20090017602 | METHOD FOR MANUFACTURING A SEMICONDUCTOR-ON-INSULATOR SUBSTRATE FOR MICROELECTRONICS AND OPTOELECTRONICS - The method includes the following steps:
| 01-15-2009 |
| 20090068821 | Charge-free low-temperature method of forming thin film-based nanoscale materials and structures on a substrate - A method of forming a nanostructure at low temperatures. A substrate that is reactive with one of atomic oxygen and nitrogen is provided. A flux of neutral atoms of least one of nitrogen and oxygen is generated within a laser-sustained-discharge plasma source and a collimated beam of energetic neutral atoms and molecules is directed from the plasma source onto a surface of the substrate to form the nanostructure. The energetic neutral atoms and molecules in the plasma have an average kinetic energy in a range from about 1 eV to about 5 eV. | 03-12-2009 |
| 20090117715 | Semiconductor device fabricated by selective epitaxial growth method - A semiconductor device in which selectivity in epitaxial growth is improved. There is provided a semiconductor device comprising a gate electrode formed over an Si substrate, which is a semiconductor substrate, with a gate insulating film therebetween and an insulating layer formed over sides of the gate electrode and containing a halogen element. With this semiconductor device, a silicon nitride film which contains the halogen element is formed over the sides of the gate electrode when an SiGe layer is formed over the Si substrate. Therefore, the SiGe layer epitaxial-grows over the Si substrate with high selectivity. As a result, an OFF-state leakage current which flows between, for example, the gate electrode and source/drain regions is suppressed and a manufacturing process suitable for actual mass production is established. | 05-07-2009 |
| 20090142908 | METHOD OF MANUFACTURING PHOTOELECTRIC CONVERSION DEVICE - A photoelectric conversion device having an excellent photoelectric conversion characteristic is provided while effectively utilizing limited resources. A fragile layer is formed in a region at a depth of less than 1000 nm from one surface of a single crystal semiconductor substrate, and a first impurity semiconductor layer, a first electrode, and an insulating layer are formed on the one surface side of the single crystal semiconductor substrate. After bonding the insulating layer to a supporting substrate, the single crystal semiconductor substrate is separated with the fragile layer or its vicinity used as a separation plane, thereby forming a first single crystal semiconductor layer over the supporting substrate. A second single crystal semiconductor layer is formed by epitaxially growing a semiconductor layer on the first single crystal semiconductor layer in accordance with a plasma CVD method in which a silane based gas and hydrogen with a flow rate 50 times or more that of the silane gas are used as a source gas. A second impurity semiconductor layer which has a conductivity type opposite to that of the first impurity semiconductor layer is formed over the second single crystal semiconductor layer. A second electrode is formed over the second impurity semiconductor layer. | 06-04-2009 |
| 20090176353 | CRYSTALLINE-TYPE DEVICE AND APPROACH THEREFOR - Single-crystalline growth is realized using a liquid-phase crystallization approach involving the inhibition of defects typically associated with liquid-phase crystalline growth of lattice mismatched materials. According to one example embodiment, a semiconductor device structure includes a substantially single-crystal region. A liquid-phase material, such as Ge or a semiconductor compound, is crystallized to form the single-crystal region using an approach involving defect inhibition for the promotion of single-crystalline growth. In some instances, this defect inhibition involves the reduction and/or elimination of defects using a relatively small physical opening via which a crystalline growth front propagates. In other instances, this defect inhibition involves causing a change in crystallization front direction relative to a crystallization seed location. The relatively small physical opening and/or the change in crystalline front direction may be implemented, for example, using a material that is substantially unreactive with the liquid-phase material to contain the crystalline growth. | 07-09-2009 |
| 20090215248 | AlxInyGa1-x-yN MIXTURE CRYSTAL SUBSTRATE, METHOD OF GROWING SAME AND METHOD OF PRODUCING SAME - Seeds are implanted in a regular pattern upon an undersubstrate. An Al | 08-27-2009 |
| 20090221134 | Semiconductor Device and Method of Manufacturing Semiconductor Device - A method of manufacturing a semiconductor device that includes a first and second device regions on a substrate. The method includes the steps of forming an insulation layer on the substrate, laminating a first semiconductor layer having a plane orientation different from the surface of the substrate on the insulation layer and exposing the substrate by removing the insulation layer and the first semiconductor layer from the second device region. A second semiconductor layer having the same plane orientation as the substrate and that is made of a strained layer is formed by epitaxial growth on the exposed substrate in the second device region. | 09-03-2009 |
| 20090275190 | METHOD FOR FORMING BUFFER LAYER FOR GaN SINGLE CRYSTAL - Disclosed is a method for forming a buffer layer for growing gallium nitride single crystals on a sapphire substrate using hydride vapor phase epitaxy (HVPE), wherein the buffer layer is formed in the form of a doped vertical gallium nitride (GaN) single crystal film with a nanoporosity of 0.10 to 0.15 μm on the sapphire substrate by reacting HCl and NH | 11-05-2009 |
| 20100035416 | Forming III-Nitride Semiconductor Wafers Using Nano-Structures - A method of forming a circuit structure includes providing a substrate; etching the substrate to form nano-structures; and growing a compound semiconductor material onto the nano-structures using epitaxial growth. Portions of the compound semiconductor material grown from neighboring ones of the nano-structures join each other to form a continuous compound semiconductor film. The method further includes separating the continuous compound semiconductor film from the substrate. | 02-11-2010 |
| 20100041214 | Single crystal substrate and method of fabricating the same - A high quality single crystal substrate and a method of fabricating the same are provided. The method of fabricating a single crystal substrate includes: forming an insulator on a substrate; forming a window in the insulator, the window exposing a portion of the substrate; forming an epitaxial growth silicon or germanium seed layer on the portion of the substrate exposed through the window; depositing a silicon or germanium material layer, which are crystallization target material layers, on the epitaxial growth silicon 6r germanium seed layer and the insulator; and crystallizing the crystallization target material layer by melting and cooling the crystallization target material layer. | 02-18-2010 |
| 20100055882 | Junction Termination Extension with Controllable Doping Profile and Controllable Width for High-Voltage Electronic Devices - Methods for producing a junction termination extension surrounding the edge of a cathode or anode junction in a semiconductor substrate, where the junction termination extension has a controlled arbitrary lateral doping profile and a controlled arbitrary lateral width, are provided. A photosensitive material is illuminated through a photomask having a pattern of opaque and clear spaces therein, the photomask being separated from the photosensitive material so that the light diffuses before striking the photosensitive material. After processing, the photosensitive material so exposed produces a laterally tapered implant mask. Dopants are introduced into the semiconductor material and follow a shape of the laterally tapered implant mask to create a controlled arbitrary lateral doping profile and a controlled lateral width in the junction termination extension in the semiconductor. | 03-04-2010 |
| 20100055883 | GROUP III-NITRIDE SEMICONDUCTOR THIN FILM, METHOD FOR FABRICATING THE SAME, AND GROUP III-NITRIDE SEMICONDUCTOR LIGHT EMITTING DEVICE - Disclosed herein is a high-quality group III-nitride semiconductor thin film and group III-nitride semiconductor light emitting device using the same. To obtain the group III-nitride semiconductor thin film, an AlInN buffer layer is formed on a (1-102)-plane (so called r-plane) sapphire substrate by use of a MOCVD apparatus under atmospheric pressure while controlling a temperature of the substrate within a range from 850 to 950 degrees Celsius, and then, GaN-based compound, such as GaN, AlGaN or the like, is epitaxially grown on the buffer layer at a high temperature. The group III-nitride semiconductor light emitting device is fabricated by using the group III-nitride semiconductor thin film as a base layer. | 03-04-2010 |
| 20100062588 | METHOD OF MANUFACTURING SEMICONDUCTOR SUBSTRATE - A method of manufacturing a semiconductor substrate, in which a silicon layer is provided on a buried oxide film, includes preparing a base substrate having a seed layer of the silicon layer on the buried oxide film with a film thickness equal to or more than 1 nm and equal to or less than 100 nm, and epitaxially growing the seed layer at a temperature equal to or more than 1000° C. and equal to or less than 1300° C. so as to form the silicon layer with a film thickness equal to or more than 1 μm and equal to or less than 20 μm. | 03-11-2010 |
| 20100075484 | SOI DEVICE WITH CONTACT TRENCHES FORMED DURING EPITAXIAL GROWING - A method for manufacturing an integrated electronic device. The method includes providing an SOI substrate having a semiconductor substrate, an insulating layer on the semiconductor substrate, and a semiconductor starting layer on the insulating layer; epitaxially growing the starting layer to obtain a semiconductor active layer on the insulating layer for integrating components of the device, and forming at least one contact trench extending from an exposed surface of the starting layer to the semiconductor substrate before the step of epitaxially growing the starting layer, wherein each contact trench clears a corresponding portion of the starting layer, of the insulating layer and of the semiconductor substrate, the epitaxial growing being further applied to the cleared portions thereby at least partially filling the at least one contact trench with semiconductor material. | 03-25-2010 |
| 20100105194 | Method of Integrating Epitaxial Film onto Assembly Substrate - A method of growing an epitaxial film and transferring it to an assembly substrate is disclosed. The film growth and transfer are made using an epitaxy lateral overgrowth technique. The formed epitaxial film on an assembly substrate can be further processed to form devices such as solar cell, light emitting diode, and other devices and assembled into higher integration of desired applications. | 04-29-2010 |
| 20100144127 | METHOD FOR REDUCING AGGLOMERATION OF Si LAYER, METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE AND VACUUM TREATMENT APPARATUS - The present invention provides a method for reducing the agglomeration of a Si layer in an SOI substrate, which can prevent the agglomeration of the Si layer from occurring in a heating and temperature-raising process for the Si layer, when heating and temperature-raising the Si layer that is the outermost surface of the SOI substrate and is in an exposed state, and can prevent the agglomeration further without forming a protective film on the SOI substrate. The method for reducing the agglomeration of the Si layer in the SOI substrate is a method of supplying a hydride gas in a heating and temperature-raising process for the Si layer, when heating and temperature-raising the Si layer which is in an exposed state in the SOI substrate that has an insulation layer and the Si layer sequentially stacked on a Si substrate. In this method, the hydride gas dissociates before the Si layer coheres, at a temperature at which the Si layer does not yet start agglomeration, and terminates a dangling bond of the Si layer with a predetermined atom such as H. | 06-10-2010 |
| 20100203713 | METHOD OF MANUFACTURING ELECTRONIC DEVICE - An object of this invention is to provide a method for manufacturing an electronic device wherein a conductor layer is uniformly formed on a substrate having a super large area. In the method for manufacturing the electronic device, a metal film for forming a gate electrode is selectively embedded in a transparent resin film formed on a substrate, and the metal film is formed by sputtering directly on the substrate at the gate electrode portion, and on an insulating coat film on portions other than the gate electrode portion. The metal film on the insulating coat film is removed by chemical liftoff with removal of the insulating coat film by etching. | 08-12-2010 |
| 20100221897 | SEMICONDUCTOR DEVICE AND METHOD OF FABRICATING THE SAME - Disclosed is a semiconductor device. The semiconductor device includes a first type nitride-based cladding layer formed on a growth substrate having an insulating property, a multi quantum well nitride-based active layer formed on the first type nitride-based cladding layer and a second type nitride-based cladding layer, which is different from the first type nitride-based cladding layer and is formed on the multi quantum well nitride-based active layer. A tunnel junction layer is formed between the undoped buffering nitride-based layer and the first type nitride-based cladding layer or/and formed on the second type nitride-based cladding layer. | 09-02-2010 |
| 20110151650 | SEMICONDUCTOR LAYER STRUCTURE AND METHOD FOR FABRICATING A SEMICONDUCTOR LAYER STRUCTURE - Semiconductor layer structure and a method for producing a structure are provided, including a substrate made of semiconductor material, on which a layer made of a second semiconductor material is situated, furthermore a region ( | 06-23-2011 |
| 20110195562 | Sputtering Apparatus, Thin-Film Forming Method, and Manufacturing Method for a Field Effect Transistor - [Object] To provide a sputtering apparatus, a thin-film forming method, and a manufacturing method for a field effect transistor, which are capable of reducing damage of a base layer. | 08-11-2011 |
| 20110250738 | METHODS OF SELECTIVELY FORMING SILICON-ON-INSULATOR STRUCTURES USING SELECTIVE EXPITAXIAL GROWTH PROCESS - A method of forming a silicon based optical waveguide can include forming a silicon-on-insulator structure including a non-crystalline silicon portion and a single crystalline silicon portion of an active silicon layer in the structure. The non-crystalline silicon portion can be replaced with an amorphous silicon portion and maintaining the single crystalline silicon portion and the amorphous portion can be crystallized using the single crystalline silicon portion as a seed to form a laterally grown single crystalline silicon portion including the amorphous and single crystalline silicon portions. | 10-13-2011 |
| 20120034765 | MANUFACTURING METHOD OF MICROCRYSTALLINE SILICON FILM AND MANUFACTURING METHOD OF THIN FILM TRANSISTOR - An object is to provide a manufacturing method of a microcrystalline silicon film with improved adhesion between an insulating film and the microcrystalline silicon film. The microcrystalline silicon film is formed in the following manner. Over an insulating film, a microcrystalline silicon grain having a height that allows the microcrystalline silicon grain to be completely oxidized by later plasma oxidation (e.g., a height greater than 0 nm and less than or equal to 5 nm), or a microcrystalline silicon film or an amorphous silicon film having a thickness that allows the microcrystalline silicon film or the amorphous silicon film to be completely oxidized by later plasma oxidation (e.g., a thickness greater than 0 nm and less than or equal to 5 nm) is formed. Plasma treatment in an atmosphere including oxygen or plasma oxidation is performed on the microcrystalline silicon grain, the microcrystalline silicon film, or the amorphous silicon film, so that a silicon oxide grain or a silicon oxide film is formed over the insulating film. A microcrystalline silicon film is formed over the silicon oxide grain or the silicon oxide film. | 02-09-2012 |
| 20120238083 | Method of Forming Epitaxial Semiconductor Structure - A method of growing an epitaxial semiconductor structure is disclosed. The growth and transfer are made using an epitaxy lateral overgrowth technique. The formed epitaxial film on an assembly substrate can be further processed to form devices such as solar cell, light emitting diode, and other devices and assembled into higher integration of desired applications. | 09-20-2012 |
| 20120238084 | Method of Forming Epitaxial Based Integrated Circuit - A method of growing an epitaxial semiconductor structure is disclosed. The growth and transfer are made using an epitaxy lateral overgrowth technique. The formed epitaxial film on an assembly substrate can be further processed to form devices such as solar cell, light emitting diode, and other devices and assembled into higher integration of desired applications. | 09-20-2012 |
| 20120264278 | EPITAXIAL LIFT OFF STACK HAVING A NON-UNIFORM HANDLE AND METHODS THEREOF - Embodiments of the invention generally relate to epitaxial lift off (ELO) thin films and devices and methods used to form such films and devices. In one embodiment, a method for forming a thin film material during an epitaxial lift off process is provided which includes forming an epitaxial material over a sacrificial layer on a substrate, adhering a non-uniform support handle onto the epitaxial material, and removing the sacrificial layer during an etching process. The etching process further includes peeling the epitaxial material from the substrate while forming an etch crevice therebetween and bending the support handle to form compression in the epitaxial material during the etching process. In one example, the non-uniform support handle contains a wax film having a varying thickness. | 10-18-2012 |
| 20130196488 | Fin Structures with Damage-Free Sidewalls for Multi-Gate Mosfets - Improved Fin Field Effect Transistors (FinFET) are provided, as well as improved techniques for forming fins for a FinFET. A fin for a FinFET is formed by forming a semi-insulating layer on an insulator that gives a sufficiently large conduction band offset (ΔE | 08-01-2013 |
| 20140357063 | MANUFACTURING METHODS OF SEMICONDUCTOR SUBSTRATES - The present invention discloses manufacturing methods of semiconductor substrates. The method includes following steps: providing a semiconductor substrate with a nucleation layer, forming a microparticle etching mask on the nucleation layer, etching the nucleation layer, filling sol-gel into etched notches of the semiconductor substrate, removing the microparticle etching mask, performing growth of epitaxy rods and performing lateral connection of the top of the epitaxy rods to form a defect-free semiconductor substrate. The production methods of the present invention can confine the defects from the nucleation layer or the epitaxy rods to the epitaxy rods so as to generate a defect-free semiconductor substrate, that is, a semiconductor substrate with a defect-free growth film, after the lateral connection of the top of the epitaxy rods. | 12-04-2014 |
| 20150056792 | FINFET AND METHOD OF FABRICATION - An improved finFET and method of fabrication is disclosed. Embodiments of the present invention take advantage of the different epitaxial growth rates of {110} and {100} silicon. Fins are formed that have {110} silicon on the fin tops and {100} silicon on the long fin sides (sidewalls). The lateral epitaxial growth rate is faster than the vertical epitaxial growth rate. The resulting merged fins have a reduced merged region in the vertical dimension, which reduces parasitic capacitance. Other fins are formed with {110} silicon on the fin tops and also {110} silicon on the long fin sides. These fins have a slower epitaxial growth rate than the {100} side fins, and remain unmerged in a semiconductor integrated circuit, such as an SRAM circuit. | 02-26-2015 |
| 20150064884 | TRENCH SIDEWALL PROTECTION FOR SELECTIVE EPITAXIAL SEMICONDUCTOR MATERIAL FORMATION - A method of forming a semiconductor device includes forming an insulator layer over a substrate; opening a trench in the insulator layer so as to expose one or more semiconductor structures formed on the substrate; forming a protective layer on sidewalls of the trench; subjecting the substrate to a precleaning operation in preparation for epitaxial semiconductor formation, wherein the protective layer prevents expansion of the sidewalls of the trench as a result of the precleaning operation; and forming epitaxial semiconductor material within the trench and over the exposed one or more semiconductor structures. | 03-05-2015 |
| 20150079771 | METHOD FOR MANUFACTURING A SEMICONDUCTOR STRUCTURE - The present disclosure provides a method for manufacturing a semiconductor structure. The method includes several operations as follows. A semiconductor substrate is received. A trench along a depth in the semiconductor substrate is formed. The semiconductor substrate is exposed in a hydrogen containing atmosphere. Dopants are inserted into a portion of the semiconductor substrate. A dielectric is filled in the trench. The dopants are driven into a predetermined distance in the semiconductor substrate. | 03-19-2015 |
| 20160049299 | Growing III-V Compound Semiconductors from Trenches Filled with Intermediate Layers - A method of forming an integrated circuit structure includes forming an insulation layer over at least a portion of a substrate; forming a plurality of semiconductor pillars over a top surface of the insulation layer. The plurality of semiconductor pillars is horizontally spaced apart by portions of the insulation layer. The plurality of semiconductor pillars is allocated in a periodic pattern. The method further includes epitaxially growing a III-V compound semiconductor film from top surfaces and sidewalls of the semiconductor pillars. | 02-18-2016 |
| 20160126093 | METHOD TO GROW THIN EPITAXIAL FILMS AT LOW TEMPERATURE - Implementations of the present disclosure generally relate to methods for epitaxial growth of a silicon material on an epitaxial film. In one implementation, the method includes forming an epitaxial film over a semiconductor fin, wherein the epitaxial film includes a top surface having a first facet and a second facet, and forming an epitaxial layer on at least the top surface of the epitaxial film by alternatingly exposing the top surface to a first precursor gas comprising one or more silanes and a second precursor gas comprising one or more chlorinated silanes at a temperature of about 375° C. to about 450° C. and a chamber pressure of about 5 Torr to about 20 Torr. | 05-05-2016 |
