Class / Patent application number | Description | Number of patent applications / Date published |
438473000 | By implanting or irradiating | 56 |
20080254598 | Laser Irradiation Method, Laser Irradiation Apparatus, And Semiconductor Device - An object of the present invention is obtaining a semiconductor film with uniform characteristics by improving irradiation variations of the semiconductor film. The irradiation variations are generated due to scanning while irradiating with a linear laser beam of the pulse emission. At a laser crystallization step of irradiating a semiconductor film with a laser light, a continuous light emission excimer laser emission device is used as a laser light source. For example, in a method of fabricating an active matrix type liquid crystal display device, a continuous light emission excimer laser beam is irradiated to a semiconductor film, which is processed to be a linear shape, while scanning in a vertical direction to the linear direction. Therefore, more uniform crystallization can be performed because irradiation marks can be avoided by a conventional pulse laser. | 10-16-2008 |
20080311728 | METHOD FOR RECOVERING DAMAGE OF LOW DIELECTRIC INSULATING FILM AND METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - There is provided a damage recovery method capable of recovering electrical characteristics of a low dielectric insulating film sufficiently while suppressing oxidation of buried metal and generation of pattern defaults. | 12-18-2008 |
20090047772 | Method for Improving the Quality of a SiC Crystal - A method for improving the quality of a SiC layer by effectively reducing or eliminating the carrier trapping centers in the as-grown SiC crystal. The method includes the steps of: (a) carrying out ion implantation of carbon atoms, silicon atoms, hydrogen atoms, or helium atoms into a shallow surface layer of the SiC crystal layer to introduce carbon interstitials into the surface layer, and (b) growing the SiC layer upward from the edge face of the surface layer into which the carbon interstitials have been introduced, and diffusing out the carbon interstitials that have been introduced into the surface layer from the surface layer into the grown layer and combining the carbon interstitials and point defects to make the electrically active point defects in the grown layer inactive. | 02-19-2009 |
20090176350 | INTEGRATION OF ION GETTERING MATERIAL IN DIELECTRIC - A method embodiment deposits a first dielectric layer over a transistor and then implants a gettering agent into the first dielectric layer. After this first dielectric layer is formed, the method forms a second (thicker) dielectric layer over the first dielectric layer. After this, the standard contacts are formed through the insulating layer to the source, drain, gate, etc. of the transistor. Additionally, reactive ion etching, chemical mechanical processing, and other back-end-of-line processing are performed. The back-end-of-line processes can introduce mobile ions into the dielectric over a transistor; however, the gettering agent traps the mobile ions and prevents the mobile ions from contaminating the transistor. | 07-09-2009 |
20090176351 | STRUCTURE AND METHOD TO IMPROVE MOSFET RELIABILITY - A method embodiment deposits a dielectric layer over a transistor and then implants a gettering agent into the dielectric layer. The insulating layer into which the gettering agent is implanted comprises a single continuous insulating layer and is the insulating layer that borders the next layer of metallization. After this dielectric layer is formed, standard contacts (tungsten) are formed through the insulating layer to the source, drain, gate, etc. of the transistor. Additionally, reactive ion etching of the contacts is performed. The reactive ion etching process can create mobile ions; however, the gettering agent traps the mobile ions and prevents the mobile ions from contaminating the transistor. | 07-09-2009 |
20090197396 | Method for Producing Silicon Wafer - The present invention provides a method for producing a silicon wafer at least including a step of performing RTA heat treatment with respect to a silicon wafer in an atmospheric gas, wherein nitrogen gas is used as the atmospheric gas, which is mixed with oxygen at a concentration of less than 100 ppm so as to perform the heat treatment. Hereby a method for producing a high-quality wafer can be provided, where the RTA heat treatment subject to the silicon wafer can be performed at a low temperature or over a short period of time, so that generation of slip dislocation of the silicon wafer can be suppressed, and at the same time vacancies can be implanted inside the silicon wafer without using NH | 08-06-2009 |
20090280623 | Method Of Producing Semiconductor Wafer - A semiconductor wafer is produced by irradiating a laser beam to either face of a semiconductor wafer so as to fit a focusing position into a given depth position of the semiconductor wafer to generate a multiphoton absorption process only in a specific portion of the semiconductor wafer at the given depth position to thereby form a gettering sink. | 11-12-2009 |
20090311850 | METHOD FOR SURFACE TREATMENT OF SEMICONDUCTOR SUBSTRATES - Methods and apparatus for processing a substrate are provided herein. In some embodiments, a method of processing a substrate may include providing a substrate having at least one of a defect or a contaminant disposed on or near a surface of the substrate; and selectively annealing a portion of the substrate with a laser beam in the presence of a process gas comprising hydrogen. The laser beam may be moved over the substrate or continuously, or in a stepwise fashion. The laser beam may be applied in a continuous wave or pulsed mode. The process gas may further comprise an inert gas, such as, at least one of helium, argon, or nitrogen. A layer of material may be subsequently deposited atop the annealed substrate. | 12-17-2009 |
20100009520 | WAFER PROCESSING METHOD FOR IMPROVING GETTERING CAPABILITIES OF WAFERS MADE THEREFROM - A wafer processing method for improving gettering capabilities of wafers made therefrom is presented. The method includes the steps of preparing, annealing and ion-implanting. The preparing step involves preparing the wafer from a silicon ingot. The annealing step involves forming first gettering sites in both sides of the wafer by annealing the wafer. The ion-implanting step involves forming second gettering sites in a back side of the wafer in which the first gettering sites are already formed. | 01-14-2010 |
20100009521 | METHOD OF PRODUCING SEMICONDUCTOR WAFER - There is provided a production method in which the beveling step conducted for preventing the cracking or chipping in a raw wafer during the grinding can be omitted when the raw wafer cut out from a crystalline ingot is processed into a double-side mirror-finished semiconductor wafer and a semiconductor wafer can be obtained cheaply by shortening the whole of the production steps for the semiconductor wafer and decreasing the machining allowance of silicon material in the semiconductor wafer to reduce the kerf loss of the semiconductor material as compared with the conventional method. | 01-14-2010 |
20100022072 | Semiconductor Fabrication - This document discloses devices fabricated on a semiconductor substrate and methods of fabricating the same. The devices can be memory cells having a tunnel window that is defined by dry-etching oxide to expose the semiconductor substrate and growing a tunnel oxide layer on the exposed semiconductor substrate. The semiconductor substrate can be decontaminated and/or repaired by exposing the semiconductor substrate to an optical irradiated energy source having a predefined energy that is sufficient to break molecular bonds of the contaminants and exposing the semiconductor substrate to a temperature that is sufficient to recrystallize the crystal lattice of the substrate. | 01-28-2010 |
20100081259 | DISLOCATION ENGINEERING USING A SCANNED LASER - A method for generating patterned strained regions in a semiconductor device is provided. The method includes directing a light-emitting beam locally onto a surface portion of a semiconductor body; and manipulating a plurality of dislocations located proximate to the surface portion of the semiconductor body utilizing the light-emitting beam, the light-emitting beam being characterized as having a scan speed, so as to produce the patterned strained regions. | 04-01-2010 |
20100093156 | METHOD FOR PRODUCTION OF SILICON WAFER FOR EPITAXIAL SUBSTRATE AND METHOD FOR PRODUCTION OF EPITAXIAL SUBSTRATE - A method for producing a silicon wafer for epitaxial substrate which includes a first step of performing thermal oxidization on a silicon wafer containing boron atoms no less than 1E19 atoms/cm | 04-15-2010 |
20100112788 | METHOD TO REDUCE SURFACE DAMAGE AND DEFECTS - A method of implantation that minimizes surface damage to a workpiece is disclosed. In one embodiment, following a doping implant, a second implant is performed which causes the silicon at the surface of the workpiece to become amorphous. This reduces surface damage and interstitials, which has several benefits. First, inactive dopant clusters may become activated due to the replenishment of silicon. Secondly, the amorphous nature of the silicon makes it bond more easily in subsequent process steps, such as silicidation. | 05-06-2010 |
20100173475 | Method for Improving the Quality of a SiC Crystal - A method for improving the quality of a SiC layer by effectively reducing or eliminating the carrier trapping centers in the as-grown SiC crystal. The method includes the steps of: (a) carrying out ion implantation of carbon atoms, silicon atoms, hydrogen atoms, or helium atoms into a shallow surface layer of the SiC crystal layer to introduce carbon interstitials into the surface layer, and (b) growing the SiC layer upward from the edge face of the surface layer into which the carbon interstitials have been introduced, and diffusing out the carbon interstitials that have been introduced into the surface layer from the surface layer into the grown layer and combining the carbon interstitials and point defects to make the electrically active point defects in the grown layer inactive. | 07-08-2010 |
20100178753 | SILICON WAFER AND METHOD FOR MANUFACTURING THE SAME - A method for manufacturing a silicon wafer includes a step of annealing a silicon wafer which is sliced from a silicon single crystal ingot, thereby forming a DZ layer in a first surface and in a second surface of the silicon wafer and a step of removing either a portion of the DZ layer in the first surface or a portion of the DZ layer in the second surface. | 07-15-2010 |
20100203708 | AMORPHIZATION/TEMPLATED RECRYSTALLIZATION METHOD FOR HYBRID ORIENTATION SUBSTRATES - The present invention provides an improved amorphization/templated recrystallization (ATR) method for fabricating low-defect-density hybrid orientation substrates. ATR methods for hybrid orientation substrate fabrication generally start with a Si layer having a first orientation bonded to a second Si layer or substrate having a second orientation. Selected regions of the first Si layer are amorphized and then recrystallized into the orientation of the second Si layer by using the second Si layer as a template. The process flow of the present invention solves two major difficulties not disclosed by prior art ATR methods: the creation of “corner defects” at the edges of amorphized Si regions bounded by trenches, and undesired orientation changes during a high temperature post-recrystallization defect-removal annealing of non-ATR'd regions not bounded by trenches. In particular, this invention provides a process flow comprising the steps of (i) amorphization and low-temperature recrystallization performed in substrate regions free of trenches, (ii) formation of trench isolation regions that subsume the defective regions at the edge of the ATR'd regions, and (iii) a high-temperature defect-removal anneal performed with the trench isolation regions in place. | 08-12-2010 |
20100304552 | METHOD AND APPARATUS FOR MANUFACTURING SEMICONDUCTOR SUBSTRATE DEDICATED TO SEMICONDUCTOR DEVICE, AND METHOD AND APPARATUS FOR MANUFACTURING SEMICONDUCTOR DEVICE - A method for manufacturing a semiconductor substrate dedicated to a semiconductor device, in which multi-photon absorption is generated in a micro-region inside the semiconductor substrate by condensing laser beams in any micro-region inside the semiconductor substrate, and a gettering sink is formed by changing the crystal structure of only the micro-region. | 12-02-2010 |
20110053349 | APPLICATION OF MILLISECOND HEATING SOURCE FOR SURFACE TREATMENT - A method for fabricating semiconductor devices, e.g., strained silicon MOS device, includes providing a semiconductor substrate (e.g., silicon wafer) having a surface region, which has one or more contaminants and an overlying oxide layer. The one or more contaminants is at least a carbon species. The method also includes processing the surface region using at least a wet process to selectively remove the oxide layer and expose the surface region. The method further includes subjecting the surface region to a laser treatment process for a time period of less than 1 second to increase a temperature of the surface region to greater than 1000 degrees Celsius to remove the one or more contaminants provided on the surface region. The method also includes removing the laser treatment process to cause a reduction in temperature to about 300 to about 600 degrees Celsius in a time period of less than 1 second. | 03-03-2011 |
20110053350 | SILICON WAFER - A silicon wafer which has DZ layers formed on both sides thereof by heat treatment in an atmosphere of reducing gas (such as hydrogen) or rare gas (such as argon) with a specific temperature profile for heating, holding, and cooling, and which also has a gettering site of BMD in the bulk inside the DZ layer. A silicon wafer which has a silicon epitaxial layer formed on one side thereof. The DZ layer and the silicon epitaxial layer contain dissolved oxygen introduced into their surface parts, with the concentration and distribution of dissolved oxygen properly controlled. Introduction of oxygen into the surface part is accomplished by heat treatment and ensuing rapid cooling in an atmosphere of oxygen-containing gas. | 03-03-2011 |
20110086494 | METHOD OF REMOVING HEAVY METAL IN SEMICONDUCTOR SUBSTRATE - To provide a method of removing a heavy metal contained in a thinned semiconductor substrate. | 04-14-2011 |
20110092054 | Methods for fixing graphene defects using a laser beam and methods of manufacturing an electronic device - Methods of fixing graphene using a laser beam and methods of manufacturing an electronic device are provided, the method of fixing graphene includes fixing a defect of a graphene nanoribbon by irradiating the laser beam onto the graphene nanoribbon. | 04-21-2011 |
20110183496 | METHOD OF MANUFACTURING A SEMICONDUCTOR DEVICE AND SUBSTRATE CARRIER STRUCTURE - A substrate carrier structure includes a tray and a secondary electron absorbing material. The tray holds a semiconductor substrate having a first surface on which semiconductor device elements are formed. The secondary electron absorbing material is interposed between the tray and this first surface of the semiconductor substrate. When the semiconductor substrate is irradiated with charged particles to form lattice defects, the secondary electron absorbing material prevents unwanted trapping of secondary electrons emitted from the tray, and thereby reduces the variability of electrical characteristics of semiconductor device elements formed on the semiconductor substrate. | 07-28-2011 |
20130178046 | METHOD OF MANUFACTURING A SEMICONDUCTOR APPARATUS - A method of manufacturing a semiconductor apparatus is disclosed. A first-type doped layer, a second-type doped layer, and an internal electrical connection layer are formed. The internal electrical connection layer is deposited and electrically coupled between the first-type doped layer and the second-type doped layer. In one embodiment, the internal electrical connection layer is formed by using a group IV based precursor and nitrogen based precursor. In another embodiment, the internal electrical connection layer is formed by a mixture comprising a carbon-contained doping source, and the internal electrical connection layer has a carbon concentration greater than 10 | 07-11-2013 |
20130273719 | METHOD OF MANUFACTURING ANNEALED WAFER - Annealed wafers having reduced residual voids after annealing and reduced deterioration of TDDB characteristics of an oxide film formed on the annealed wafer, while extending the range of nitrogen concentration contained in a silicon single crystal, are prepared by a method wherein crystal pulling conditions are controlled such that a ratio V/G between a crystal pulling rate V and an average axial temperature gradient G is ≧0.9×(V/G) | 10-17-2013 |
20140024200 | FILM DEPOSITION APPARATUS AND FILM DEPOSITION METHOD - A film deposition apparatus includes a turntable to rotate a substrate thereon, a process gas supply part to supply a process gas to form a thin film on the substrate, a heating part to heat the substrate up to a predetermined film deposition temperature to form a thin film, a plasma treatment part to treat the thin film for modification, a heat lamp provided above the turntable and configured to heat the substrate up to a temperature higher than the predetermined film deposition temperature by irradiating the substrate with light in an adsorption wavelength range of the substrate, and a control part to output a control signal so as to repeat a step of depositing the thin film and a step of modifying the thin film by the plasma, and then to stop supplying the process gas and to heat the substrate by the heat lamp. | 01-23-2014 |
20140080289 | METHOD OF FORMING GETTERING LAYER - Disclosed herein is a method of forming a gettering layer for capturing metallic ions on the back side of a semiconductor wafer formed with devices on the face side thereof. The method includes irradiating the back-side surface of the semiconductor wafer with a pulsed laser beam having a pulse width corresponding to a thermal diffusion length of 10 to 230 nm, to thereby form the gettering layer. | 03-20-2014 |
20140154872 | DISLOCATION ENGINEERING USING A SCANNED LASER - A method for generating patterned strained regions in a semiconductor device is provided. The method includes directing a light-emitting beam locally onto a surface portion of a semiconductor body; and manipulating a plurality of dislocations located proximate to the surface portion of the semiconductor body utilizing the light-emitting beam, the light-emitting beam being characterized as having a scan speed, so as to produce the patterned strained regions. | 06-05-2014 |
20140154873 | DISLOCATION ENGINEERING USING A SCANNED LASER - A system for manipulating dislocations on semiconductor devices, includes a moveable laser configured to generate a laser beam locally on a surface portion of the semiconductor body having a plurality of dislocations, the moveable laser being characterized as having a scan speed, the moveable laser manipulates the plurality of dislocations on the surface portion of the semiconductor body by adjusting the temperature and the scan speed of the laser beam. | 06-05-2014 |
20140170837 | Methods for Manufacturing Semiconductor Devices - A method for reducing defects from an active layer is disclosed. The active layer may be part of a semiconductor in a semiconductor device. The active layer may be defined at least laterally by an isolation structure, and may physically contact an isolation structure at a contact interface. The isolation structure and the active layer may abut on a common substantially planar surface. The method may include providing a patterned stress-inducing layer on the common substantially planar surface. The stress-inducing layer may be adapted for inducing a stress field in the active layer, and induced stress field may result in a shear stress on a defect in the active layer. The method may also include performing an anneal step after providing the patterned stress-inducing layer on the common substantially planar surface. The method may additionally include removing the patterned stress-inducing layer from the common substantially planar surface. | 06-19-2014 |
20140187021 | METHOD OF HEALING DEFECT AT JUNCTION OF SEMICONDUCTOR DEVICE USING GERMANIUM - This invention relates to a method of healing defects at junctions of a semiconductor device, which includes growing a p-Ge layer on a substrate, performing ion implantation on the p-Ge layer to form an n+ Ge region or performing in-situ doping on the p-Ge layer and then etching to form an n+ Ge region or depositing an oxide film on the p-Ge layer and performing patterning, etching and in-situ doping to form an n+ Ge layer, forming a capping oxide film, performing annealing at 600˜700° C. for 1˜3 hr, and depositing an electrode, and in which annealing enables Ge defects at n+/p junctions to be healed and the depth of junctions to be comparatively reduced, thus minimizing leakage current, thereby improving properties of the semiconductor device and achieving high integration and fineness of the semiconductor device. | 07-03-2014 |
20140193964 | METHOD OF MANUFACTURING SEMICONDUCTOR DEVICE - The present invention provides a method of manufacturing a semiconductor device. The method at least comprises the following steps. First, the semiconductor device, which comprises a gate, a gate dielectric layer, an active layer, a source and a drain, is manufactured. However, the semiconductor device has a plurality of defects, and the active layer is a metal oxide thin film. After annealing the semiconductor device, it will be transferred into a chamber. A final step of injecting a supercritical fluid carried with a co-solvent into the chamber is then performed to modify the abovementioned defects. | 07-10-2014 |
20140273404 | Advanced Targeted Microwave Degas System - In some embodiments, methods are described that allow the processing of a substrate using microwave-based degas systems. The methods allow process variables such as power, dwell time, frequency, backside cooling gas usage, backside cooling gas flow rate, and the like to be investigated. In some embodiments, apparatus are described that allow the investigation of process variables used in microwave-based degas systems to remove adsorbed species from the surface of a substrate. The apparatus allow process variables such as power, dwell time, frequency, backside cooling gas usage, backside cooling gas flow rate, and the like to be investigated. | 09-18-2014 |
20140273405 | SEMICONDUCTOR-ON-INSULATOR WAFER MANUFACTURING METHOD FOR REDUCING LIGHT POINT DEFECTS AND SURFACE ROUGHNESS - A method for reducing light point defects of a semiconductor-on-insulator structure and a method for reducing the surface roughness of a semiconductor-on-insulator structure are disclosed. The methods can include a combination of thermally annealing the structure followed by a non-contact smoothing process. | 09-18-2014 |
20150017785 | METHOD OF FORMING SALICIDE BLOCK WITH REDUCED DEFECTS - A method of forming a salicide block with reduced defects is disclosed, the method including performing an ultraviolet cure process on a silicon nitride layer deposited in a previous step. High-energy ultraviolet light used in the ultraviolet cure process breaks the hydrogen-containing chemical bonds such as silicon-hydrogen and nitrogen-hydrogen in the silicon nitride layer, and the dissociated hydrogen forms molecular hydrogen which is thereafter evacuated away by a vacuuming apparatus. In this way, the hydrogen content in the silicon nitride layer can be effectively decreased and the reaction between hydrogen in the silicon nitride layer and photoresist subsequently coated thereon can hence be reduced. As a result, a salicide block with reduced defects can be obtained, thus improving process reliability and product yield. | 01-15-2015 |
20150294881 | Microwave Anneal (MWA) for Defect Recovery - The embodiments of processes and structures described above provide mechanisms for annealing defects by microwave anneal (MWA). MWA causes ionic/atomic (ionic and/or atomic) polarization, electronic polarization, and/or interfacial polarization in a substrate with dopants, damages, and interfaces in crystalline structures. The polarizations make the local temperatures higher than the substrate temperature. As a result, MWA can remove damages at a relatively low substrate temperature than other anneal mechanisms and is able to prevent undesirable dopant diffusion. The relatively low substrate temperature also makes MWA compatible with advanced processing technologies which demands lower substrate temperatures during front-end processing. MWA used in annealing defects (or damages) created in forming source and drain regions improves NMOS transistor performance. | 10-15-2015 |
20160005623 | METHOD FOR PURIFYING METALLURGICAL SILICON - The present disclosure provides a method for upgrading materials, for example crystalline metallurgical silicon, to remove impurities using microwave processing to induce migration of impurities in the material to one or both of internal surfaces where they are trapped and neutralized or one or more external surfaces followed by trapping of the impurity by binding to gettering agents on the surface with subsequent removal of the impurity and gettering agent. | 01-07-2016 |
20160093509 | SEMICONDUCTOR DEVICE AND METHOD FOR FORMING THE SAME - A semiconductor device in which a gettering layer is formed in a semiconductor substrate, and a method for forming the same are disclosed, resulting in increased reliability of the semiconductor substrate including the gettering layer. The semiconductor device includes a semiconductor substrate; a gettering layer formed of a first-type impurity and a second-type impurity in the semiconductor substrate so as to perform gettering of metal ion; and a deep-well region formed over the gettering layer in the semiconductor substrate. | 03-31-2016 |
20160155652 | METHOD OF DEGASSING | 06-02-2016 |
438474000 | Ionized radiation (e.g., corpuscular or plasma treatment, etc.) | 17 |
20090104754 | METHOD TO IMPROVE ELECTRICAL LEAKAGE PERFORMANCE AND TO MINIMIZE ELECTROMIGRATION IN SEMICONDUCTOR DEVICES - Embodiments of methods for improving electrical leakage performance and minimizing electromigration in semiconductor devices are generally described herein. Other embodiments may be described and claimed. | 04-23-2009 |
20090246939 | METHOD FOR DEHYDROGENATION TREATMENT AND METHOD FOR FORMING CRYSTALLINE SILICON FILM - A dehydrogenation treatment method which includes forming a hydrogenated amorphous silicon film above a non-heat-resistant substrate, and eliminating bonded hydrogen from the hydrogenated amorphous silicon film by irradiating an atmospheric thermal plasma discharge to the hydrogenated amorphous silicon film for a time period of 1 to 500 ms. The surface of the substrate is heated at a temperature of 1000 to 2000° C. by irradiating the atmospheric thermal plasma discharge. | 10-01-2009 |
20100173476 | METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - A method for manufacturing a semiconductor device according to the invention irradiates a first pulse laser beam with an irradiation energy density of 1.0 J/cm | 07-08-2010 |
20110244660 | MANUFACTURING METHOD OF SEMICONDUCTOR SUBSTRATE AND MANUFACTURING METHOD OF SEMICONDUCTOR DEVICE - An object is to provide a manufacturing method of a semiconductor substrate provided with a single crystal semiconductor layer with a surface having a high degree of flatness. Another object is to manufacture a semiconductor device with high reliability by using the semiconductor substrate provided with a single crystal semiconductor layer with a high degree of flatness. In a manufacturing process of a semiconductor substrate, a thin embrittled region containing a large crystal defect is formed in a single crystal semiconductor substrate at a predetermined depth by subjecting the single crystal semiconductor substrate to a rare gas ion irradiation step, a laser irradiation step, and a hydrogen ion irradiation step. Then, by performing a separation heating step, a single crystal semiconductor layer that is on a surface side than the embrittled region is transferred to a base substrate. | 10-06-2011 |
20140024201 | METHOD FOR FABRICATING SEMICONDUCTOR DEVICE - A method for fabricating a semiconductor device include forming devices on a front side of a semiconductor substrate, forming a hydrogen-containing layer on a back side of the semiconductor substrate, forming an outgassing prevention layer over the hydrogen-containing layer, and performing a hydrogen treatment process to diffuse hydrogen, contained in the hydrogen-containing layer, into the semiconductor substrate. | 01-23-2014 |
20140162435 | Ion Implant For Defect Control - Various methods for implanting dopant ions into a three dimensional feature of a semiconductor wafer are disclosed. The implant temperature may be varied to insure that the three dimensional feature, after implant, has a crystalline inner core, which is surrounded by an amorphized surface layer. The crystalline core provides a template from which the crystalline structure for the rest of the feature can be regrown. In some embodiments, the implant energy and the implant temperature may each be modified to achieve the desired crystalline inner core with the surrounding amorphized surface layer. | 06-12-2014 |
20140273406 | PROCESSING SYSTEMS AND METHODS FOR HALIDE SCAVENGING - Systems, chambers, and processes are provided for controlling process defects caused by moisture contamination. The systems may provide configurations for chambers to perform multiple operations in a vacuum or controlled environment. The chambers may include configurations to provide additional processing capabilities in combination chamber designs. The methods may provide for the limiting, prevention, and correction of aging defects that may be caused as a result of etching processes performed by system tools. | 09-18-2014 |
20150064880 | POST ETCH TREATMENT TECHNOLOGY FOR ENHANCING PLASMA-ETCHED SILICON SURFACE STABILITY IN AMBIENT - Methods for performing post etch treatments on silicon surfaces etched using halogen chemistry are provided. The methods may be performed in-situ a chamber in which the silicon surfaces where etch, ex-situ the chamber, or in a hybrid process that combines both in-situ and ex-situ post etch treatment processes. In one embodiment the post etch treatment process includes exposing a substrate having a silicon surface etched using halogen chemistry to a gas mixture comprising C | 03-05-2015 |
20150303065 | PRETREATMENT METHOD FOR PHOTORESIST WAFER PROCESSING - Certain embodiments herein relate to methods and apparatus for processing a partially fabricated semiconductor substrate in a remote plasma environment. The methods may be performed in the context of wafer level packaging (WLP) processes. The methods may include exposing the substrate to a reducing plasma to remove photoresist scum and/or oxidation from an underlying seed layer. In some cases, photoresist scum is removed through a series of plasma treatments involving exposure to an oxygen-containing plasma followed by exposure to a reducing plasma. In some embodiments, an oxygen-containing plasma is further used to strip photoresist from a substrate surface after electroplating. This plasma strip may be followed by a plasma treatment involving exposure to a reducing plasma. The plasma treatments herein may involve exposure to a remote plasma within a plasma treatment module of a multi-tool electroplating apparatus. | 10-22-2015 |
438475000 | Hydrogen plasma (i.e., hydrogenization) | 8 |
20080242059 | Methods of forming nickel silicide layers with low carbon content - A method for forming a nickel silicide layer on a MOS device with a low carbon content comprises providing a substrate within an ALD reactor and performing an ALD process cycle to form a nickel layer on the substrate, wherein the ALD process cycle comprises pulsing a nickel precursor into the reactor, purging the reactor after the nickel precursor, pulsing a mixture of hydrogen and silane into the reactor, and purging the reactor after the hydrogen and silane pulse. The ALD process cycle can be repeated until the nickel layer reaches a desired thickness. The silane used in the ALD process functions as a getterer for the advantageous carbon, resulting in a nickel layer that has a low carbon content. The nickel layer may then be annealed to form a nickel silicide layer with a low carbon content. | 10-02-2008 |
20110008950 | Remote Hydrogen Plasma With Ion Filter for Terminating Silicon Dangling Bonds - Apparatus and methods for repairing silicon dangling bonds resulting from semiconductor processing are disclosed. The silicon dangling bonds can be repaired by introducing hydrogen radicals with substantially no hydrogen ions into the processing chamber to react with the silicon dangling bonds, eliminating them. | 01-13-2011 |
20110053351 | Solar Cell Defect Passivation Method - The present disclosure passivates solar cell defects. Plasma immersion ion implantation (PIII) is used to repair the defects during or after making the solar cell. Hydrogen ion is implanted into absorption layer with different sums of energy to fill gaps of defects or surface recombination centers. Thus, solar cell defects are diminished and carriers are transferred with improved photovoltaic conversion efficiency. | 03-03-2011 |
20110275195 | METHOD OF TREATING A SEMICONDUCTOR DEVICE - A method of treating a semiconductor device wherein there is provided a semiconductor device, the semiconductor device being at least in part chemically bonded to an undesired chemical species. The semiconductor device is subjected to light of a wavelength sufficient to cleave at least some of the chemical bonds between the semiconductor device and the undesired chemical species, and the semiconductor device is exposed to a source of a desired chemical species, such that the semiconductor device becomes at least in part chemically bonded to the desired chemical species. | 11-10-2011 |
20140051234 | HYDROGEN PASSIVATION OF INTEGRATED CIRCUITS - An integrated circuit with a passivation trapping layer. An integrated circuit with a hydrogen or deuterium releasing layer underlying a passivation trapping layer. Method for forming an integrated circuit having a hydrogen or deuterium releasing layer. Method for forming an integrated circuit having a passivation trapping layer. | 02-20-2014 |
20140065798 | METHOD AND APPARATUS FOR FORMING GATE STACK ON Si, SiGe or Ge CHANNELS - Provided are methods and apparatus for functionalizing a substrate surface used as the channel in a gate stack. Silicon, germanium and silicon germanium substrates surfaces are functionalized with one or more of sulfur and selenium by plasma processing. | 03-06-2014 |
20150050798 | PRODUCTION METHOD FOR A SEMICONDUCTOR DEVICE - A method for producing a semiconductor device includes providing a semiconductor substrate having a first conductivity type; implanting protons through a rear surface of the semiconductor substrate of the first conductivity type; and forming a first semiconductor region of the first conductivity type in the semiconductor substrate by performing an annealing process in an annealing furnace in a hydrogen atmosphere having a volume concentration of hydrogen that is equal to or greater than 0.5% and less than 4.65%, the first semiconductor region having a higher impurity concentration than that of the semiconductor substrate after the implantation step. The method reduces crystal defects in the generation of donors during proton implantation and improves the rate of change into a donor. | 02-19-2015 |
20150294877 | HYDROGENATION METHOD AND HYDROGENATION APPARATUS - A hydrogenation method according to the present invention includes preparing a plasma generation section ( | 10-15-2015 |