Patent application number | Description | Published |
20080286982 | PLASMA IMMERSION ION IMPLANTATION WITH HIGHLY UNIFORM CHAMBER SEASONING PROCESS FOR A TOROIDAL SOURCE REACTOR - A method is provided for performing plasma immersion ion implantation with a highly uniform seasoning film on the interior of a reactor chamber having a ceiling and a cylindrical side wall and a wafer support pedestal facing the ceiling. The method includes providing a gas distribution ring with plural gas injection orifices on a periphery of a wafer support pedestal, the orifices facing radially outwardly from the wafer support pedestal. Silicon-containing gas is introduced through the gas distribution orifices of the ring to establish a radially outward flow pattern of the silicon-containing gas. The reactor includes pairs of conduit ports in the ceiling adjacent the side wall at opposing sides thereof and respective external conduits generally spanning the diameter of the chamber and coupled to respective pairs of the ports. The method further includes injecting oxygen gas through the conduit ports into the chamber to establish an axially downward flow pattern of oxygen gas in the chamber. RF power is coupled into the interior of each of the conduits to generate a toroidal plasma current of Si | 11-20-2008 |
20090023257 | METHOD OF CONTROLLING METAL SILICIDE FORMATION - Methods of processing silicon substrates to form metal silicide layers thereover having more uniform thicknesses are provided herein. In some embodiments, a method of processing a substrate includes providing a substrate having a plurality of exposed regions comprising silicon, wherein at least two of the plurality of exposed regions have a different rate of formation of a metal silicide layer thereover; doping at least one of the exposed regions to control the rate of formation of a metal silicide layer thereover; and forming a metal silicide layer upon the exposed regions of the substrate, wherein the metal silicide layer has a reduced maximum thickness differential between the exposed regions. | 01-22-2009 |
20090065816 | MODULATING THE STRESS OF POLY-CRYSTALINE SILICON FILMS AND SURROUNDING LAYERS THROUGH THE USE OF DOPANTS AND MULTI-LAYER SILICON FILMS WITH CONTROLLED CRYSTAL STRUCTURE - In certain embodiments a method of forming a multi-layer silicon film is provided. A substrate is placed in a process chamber. An amorphous silicon film is formed on the substrate by flowing into the process chamber a first process gas comprising a silicon source gas. A polysilicon film is formed on the amorphous silicon film by flowing into the deposition chamber a first process gas mix comprising a silicon source gas and a first dilution gas mix comprising H | 03-12-2009 |
20090162996 | REMOVAL OF SURFACE DOPANTS FROM A SUBSTRATE - A method and apparatus for removing excess dopant from a doped substrate is provided. In one embodiment, a substrate is doped by surfaced deposition of dopant followed by formation of a capping layer and thermal diffusion drive-in. A reactive etchant mixture is provided to the process chamber, with optional plasma, to etch away the capping layer and form volatile compounds by reacting with excess dopant. In another embodiment, a substrate is doped by energetic implantation of dopant. A reactive gas mixture is provided to the process chamber, with optional plasma, to remove excess dopant adsorbed on the surface and high-concentration dopant near the surface by reacting with the dopant to form volatile compounds. The reactive gas mixture may be provided during thermal treatment, or it may be provided before or after at temperatures different from the thermal treatment temperature. The volatile compounds are removed. Substrates so treated do not form toxic compounds when stored or transported outside process equipment. | 06-25-2009 |
20090195777 | DOSIMETRY USING OPTICAL EMISSION SPECTROSCOPY/RESIDUAL GAS ANALYZER IN CONJUNCTION WITH ION CURRENT - The present invention generally provides methods and apparatus for controlling ion dosage in real time during plasma processes. In one embodiment, ion dosages may be controlled using in-situ measurement of the plasma from a mass distribution sensor combined with in-situ measurement from an RF probe. | 08-06-2009 |
20090197010 | Plasma immersion ion implantation using an electrode with edge-effect suppression by a downwardly curving edge - In a plasma reactor, RF bias power is applied from an RF bias power generator to a disk-shaped electrode underlying and insulated from a workpiece and having a circumferential edge underlying a circumferential edge of the workpiece. The RF bias power is sufficient to produce a high RF bias voltage on the workpiece on the order of 0.5-20 kV. Non-uniformity in distribution of plasma across the workpiece is reduced by providing a curvature in a peripheral edge annulus of said electrode whereby the peripheral annulus slopes away from the workpiece support surface. The peripheral edge annulus corresponds to a small fraction of an area of said electrode. The remainder of the electrode encircled by the peripheral annulus has a flat shape. | 08-06-2009 |
20090197401 | Plasma immersion ion implantation method using a pure or nearly pure silicon seasoning layer on the chamber interior surfaces - Plasma immersion ion implantation employing a very high RF bias voltage on an electrostatic chuck to attain a requisite implant depth profile is carried out by first depositing a partially conductive silicon-containing seasoning layer over the interior chamber surfaces prior to wafer introduction. | 08-06-2009 |
20090203197 | NOVEL METHOD FOR CONFORMAL PLASMA IMMERSED ION IMPLANTATION ASSISTED BY ATOMIC LAYER DEPOSITION - Embodiments of the invention provide a novel apparatus and methods for forming a conformal doped layer on the surface of a substrate. A substrate is provided to a process chamber, and a layer of dopant source material is deposited by plasma deposition, atomic layer deposition, or plasma-assisted atomic layer deposition. The substrate is then subjected to thermal processing to activate and diffuse dopants into the substrate surface. | 08-13-2009 |
20090215250 | Plasma immersion ion implantation process with reduced polysilicon gate loss and reduced particle deposition - In plasma immersion ion implantation of a polysilicon gate, a hydride of the dopant is employed as a process gas to avoid etching the polysilicon gate, and sufficient argon gas is added to reduce added particle count to below 50 and to reduce plasma impedance fluctuations to 5% or less. | 08-27-2009 |
20090215251 | PLASMA IMMERSION ION IMPLANTATION PROCESS WITH CHAMBER SEASONING AND SEASONING LAYER PLASMA DISCHARGING FOR WAFER DECHUCKING - In a plasma immersion ion implantation process, the thickness of a pre-implant chamber seasoning layer is increased (to permit implantation of a succession of wafers without replacing the seasoning layer) without loss of wafer clamping electrostatic force due to increased seasoning layer thickness. This is accomplished by first plasma-discharging residual electrostatic charge from the thick seasoning layer. The number of wafers which can be processed using the same seasoning layer is further increased by fractionally supplementing the seasoning layer after each wafer is processed, which may be followed by a brief plasma discharging of the supplemented seasoning before processing the next wafer. | 08-27-2009 |
20090233384 | METHOD FOR MEASURING DOPANT CONCENTRATION DURING PLASMA ION IMPLANTATION - Embodiments of the invention generally provide methods for end point detection at predetermined dopant concentrations during plasma doping processes. In one embodiment, a method includes positioning a substrate within a process chamber, generating a plasma above the substrate and transmitting a light generated by the plasma through the substrate, wherein the light enters the topside and exits the backside of the substrate, and receiving the light by a sensor positioned below the substrate. The method further provides generating a signal proportional to the light received by the sensor, implanting the substrate with a dopant during a doping process, generating multiple light signals proportional to a decreasing amount of the light received by the sensor during the doping process, generating an end point signal proportional to the light received by the sensor once the substrate has a final dopant concentration, and ceasing the doping process. | 09-17-2009 |
20090280628 | PLASMA IMMERSION ION IMPLANTATION PROCESS WITH CHAMBER SEASONING AND SEASONING LAYER PLASMA DISCHARGING FOR WAFER DECHUCKING - In a plasma immersion ion implantation process, the thickness of a pre-implant chamber seasoning layer is increased (to permit implantation of a succession of wafers without replacing the seasoning layer) without loss of wafer clamping electrostatic force due to increased seasoning layer thickness. This is accomplished by first plasma-discharging residual electrostatic charge from the thick seasoning layer. The number of wafers which can be processed using the same seasoning layer is further increased by fractionally supplementing the seasoning layer after each wafer is processed, which may be followed by a brief plasma discharging of the supplemented seasoning before processing the next wafer. | 11-12-2009 |
20090294065 | CEILING ELECTRODE WITH PROCESS GAS DISPERSERS HOUSING PLURAL INDUCTIVE RF POWER APPLICATORS EXTENDING INTO THE PLASMA - A gas distribution plate is formed of a metallic body having a bottom surface with plural gas disperser orifices and an internal gas manifold feeding the orifices. Each one of an array of discrete RF power applicators held in the plate includes (a) an insulating cylindrical housing extending through the plate, a portion of the housing extending outside of the plate through the bottom surface, and (b) a conductive solenoidal coil contained within the housing, a portion of the coil lying within the portion of the housing that extends outside of the plate through the bottom surface. | 12-03-2009 |
20100112793 | CONFORMAL DOPING IN P3I CHAMBER - Methods for implanting ions into a substrate by a plasma immersion ion implanting process are provided. In one embodiment, a method for implanting ions into a substrate includes providing a substrate into a processing chamber, the substrate comprising substrate surface having one or more features formed therein and each feature having one or more horizontal surfaces and one or more vertical surfaces, generating a plasma from a gas mixture including a reacting gas adapted to produce ions, depositing a material layer on the substrate surface and on at least one horizontal surface of the substrate feature, implanting ions from the plasma into the substrate by an isotropic process into at least one horizontal surface and into at least one vertical surface, and etching the material layer on the substrate surface and the at least one horizontal surface by an anisotropic process. | 05-06-2010 |
20100112794 | DOPING PROFILE MODIFICATION IN P3I PROCESS - Methods for implanting material into a substrate by a plasma immersion ion implanting process are provided. In one embodiment, a method for implanting material into a substrate includes providing a substrate into a processing chamber, the substrate comprising a substrate surface having a material layer formed thereon, generating a first plasma of a non-dopant processing gas, exposing the material layer to the plasma of the non-dopant processing gas, generating a second plasma of a dopant processing gas including a reacting gas adapted to produce dopant ions, and implanting dopant ions from the plasma into the material layer. The method may further include a cleaning or etch process. | 05-06-2010 |
20100173484 | SAFE HANDLING OF LOW ENERGY, HIGH DOSE ARSENIC, PHOSPHORUS, AND BORON IMPLANTED WAFERS - A method of preventing toxic gas formation after an implantation process is disclosed. Certain dopants, when implanted into films disposed on a substrate, may react when exposed to moisture to form a toxic gas and/or a flammable gas. By in-situ exposing the doped film to an oxygen containing compound, dopant that is shallowly implanted into the layer stack reacts to form a dopant oxide, thereby reducing potential toxic gas and/or flammable gas formation. Alternatively, a capping layer may be formed in-situ over the implanted film to reduce the potential generation of toxic gas and/or flammable gas. | 07-08-2010 |
20100190324 | REDUCING PHOTORESIST LAYER DEGRADATION IN PLASMA IMMERSION ION IMPLANTATION - A method of plasma immersion ion implantation of a workpiece having a photoresist mask on its top surface prevents photoresist failure from carbonization of the photoresist. The method includes performing successive ion implantation sub-steps, each of the ion implantation sub-steps having a time duration over which only a fractional top portion of the photoresist layer is damaged by ion implantation. After each one of the successive ion implantation sub-steps, the fractional top portion of the photoresist is removed while leaving the remaining portion of the photoresist layer in place by performing an ashing sub-step. The number of the successive ion implantation sub-steps is sufficient to reach a predetermined ion implantation dose in the workpiece. | 07-29-2010 |
20100216258 | METHOD FOR MEASURING DOPANT CONCENTRATION DURING PLASMA ION IMPLANTATION - Embodiments of the invention generally provide methods for end point detection at predetermined dopant concentrations during plasma doping processes. In one embodiment, a method includes positioning a substrate within a process chamber, generating a plasma above the substrate and transmitting a light generated by the plasma through the substrate, wherein the light enters the topside and exits the backside of the substrate, and receiving the light by a sensor positioned below the substrate. The method further provides generating a signal proportional to the light received by the sensor, implanting the substrate with a dopant during a doping process, generating multiple light signals proportional to a decreasing amount of the light received by the sensor during the doping process, generating an end point signal proportional to the light received by the sensor once the substrate has a final dopant concentration, and ceasing the doping process. | 08-26-2010 |
20100221583 | HDD PATTERN IMPLANT SYSTEM - Methods and apparatus for forming substrates having magnetically patterned surfaces is provided. A magnetic layer comprising one or more materials having magnetic properties is formed on a substrate. The magnetic layer is subjected to a patterning process in which selected portions of the surface of the magnetic layer are altered such that the altered portions have different magnetic properties from the non-altered portions without changing the topography of the substrate. A protective layer and a lubricant layer are deposited over the patterned magnetic layer. The patterning is accomplished through a number of processes that expose substrates to energy of varying forms. Apparatus and methods disclosed herein enable processing of two major surfaces of a substrate simultaneously, or sequentially by flipping. In some embodiments, magnetic properties of the substrate surface may be uniformly altered by plasma exposure and then selectively restored by exposure to patterned energy. | 09-02-2010 |
20100258431 | USE SPECIAL ION SOURCE APPARATUS AND IMPLANT WITH MOLECULAR IONS TO PROCESS HDD (HIGH DENSITY MAGNETIC DISKS) WITH PATTERNED MAGNETIC DOMAINS - A method and apparatus for manufacturing magnetic storage media is provided. A structural substrate is coated with a magnetically susceptible material, and a patterned resist layer is formed over the magnetically susceptible material. Atom groups are directed toward the substrate, penetrating the resist and implanting into the magnetically susceptible layer. Thick portions of the resist prevent implantation in some areas to form a pattern of magnetic properties on the substrate. Energy and composition of the atom groups, thickness and hardness of the resist, and lattice energy of the magnetically susceptible material may all be adjusted to yield desired fragmentation and implantation of the atom groups, including in some embodiments mere impact on the surface without implanting. A protective layer and a lubricating layer are formed over the patterned magnetically susceptible layer. | 10-14-2010 |
20100258758 | HDD PATTERN APPARATUS USING LASER, E-BEAM, OR FOCUSED ION BEAM - A method and apparatus for manufacturing magnetic storage media is provided. A structural substrate is coated with a magnetically active material, and a magnetic pattern is formed in the magnetically active material by treating portions of the material with energy from a laser, e-beam, or focused ion beam. The beam may be divided into a packet of beamlets by passing the beam through a divider, which may be a diffraction grating for laser energy, a thin film single crystal for electrons, or a perforated plate for ions, or the beam may be generated by an array of emitters. The beamlets are then focused to a desired dimension and distribution by optics or electric fields. The resulting beam packet may be shaped further by passing through an aperture of any desired shape. The resulting beam may be applied sequentially to exposure zones to treat an entire substrate or plurality of substrates. | 10-14-2010 |
20100261040 | MODIFICATION OF MAGNETIC PROPERTIES OF FILMS USING ION AND NEUTRAL BEAM IMPLANTATION - Methods and apparatus for forming substrates having magnetically patterned surfaces is provided. A magnetic layer comprising one or more materials having magnetic properties is formed on the substrate. The magnetic layer is subjected to a patterning process in which selected portions of the surface of the magnetic layer are altered such that the altered portions have different magnetic properties from the non-altered portions without changing the topography of the substrate. A protective layer and a lubricant layer are deposited over the patterned magnetic layer. The patterning is accomplished through a number of alternative processes that expose substrates to energy of varying forms. | 10-14-2010 |
20100313951 | CARBON NANOTUBE-BASED SOLAR CELLS - Solar cells are provided with carbon nanotubes (CNTs) which are used: to define a micron/sub-micron geometry of the solar cells; and/or as charge transporters for efficiently removing charge carriers from the absorber layer to reduce the rate of electron-hole recombination in the absorber layer. A solar cell may comprise: a substrate; a multiplicity of areas of metal catalyst on the surface of the substrate; a multiplicity of carbon nanotube bundles formed on the multiplicity of areas of metal catalyst, each bundle including carbon nanotubes aligned roughly perpendicular to the surface of the substrate; and a photoactive solar cell layer formed over the carbon nanotube bundles and exposed surfaces of the substrate, wherein the photoactive solar cell layer is continuous over the carbon nanotube bundles and the exposed surfaces of the substrate. The photoactive solar cell layer may be comprised of amorphous silicon p/i/n thin films; although, concepts of the present invention are also applicable to solar cells with absorber layers of microcrystalline silicon, SiGe, carbon doped microcrystalline silicon, CIS, CIGS, CISSe and various p-type II-VI binary compounds and ternary and quaternary compounds. | 12-16-2010 |
20110006034 | METHOD FOR REMOVING IMPLANTED PHOTO RESIST FROM HARD DISK DRIVE SUBSTRATES - A method of removing resist material from a substrate having a magnetically active surface is provided. The substrate is disposed in a processing chamber and exposed to a fluorine-containing plasma formed from a gas mixture having a reagent, an oxidizing agent, and a reducing agent. A cleaning agent may also be included. The substrate may be cooled by back-side cooling or by a cooling process wherein a cooling medium is provided to the processing chamber while the plasma treatment is suspended. Substrates may be flipped over for two-sided processing, and multiple substrates may be processed concurrently. | 01-13-2011 |
20110053360 | PLASMA IMMERSED ION IMPLANTATION PROCESS USING BALANCED ETCH-DEPOSITION PROCESS - Methods for implanting ions into a substrate by a plasma immersion ion implanting process are provided. In one embodiment, a method for implanting ions into a substrate includes providing a substrate into a processing chamber, generating a plasma from a gas mixture including a reacting gas and a etching gas in the chamber, adjusting the ratio between the reacting gas and the etching gas in the supplied gas mixture and implanting ions from the plasma into the substrate. In another embodiment, the method includes providing a substrate into a processing chamber, supplying a gas mixture including reacting gas and a halogen containing reducing gas into the chamber, forming a plasma from the gas mixture, gradually increasing the ratio of the etching gas in the gas mixture, and implanting ions from the gas mixture into the substrate. | 03-03-2011 |
20110127156 | CHAMBER FOR PROCESSING HARD DISK DRIVE SUBSTRATES - An apparatus for forming a magnetic pattern in a magnetic storage substrate. A chamber comprises a chamber wall that defines an internal volume, a substrate support in the internal volume of the chamber, a gas distributor disposed in a wall region of the chamber facing the substrate support, a compact energy source for ionizing a portion of the process gas provided to the chamber, and a throttle valve having a z-actuated gate member with a sealing surface for covering an outlet portal of the chamber. Ions are accelerated toward the substrate support by an electrical bias, amplifying the ion density of the process gas. A substrate disposed on the substrate support is bombarded by the ions to alter a magnetic property of the substrate surface. | 06-02-2011 |
20110159673 | NOVEL METHOD FOR CONFORMAL PLASMA IMMERSED ION IMPLANTATION ASSISTED BY ATOMIC LAYER DEPOSITION - Embodiments of the invention provide a novel apparatus and methods for forming a conformal doped layer on the surface of a substrate. A substrate is provided to a process chamber, and a layer of dopant source material is deposited by plasma deposition, atomic layer deposition, or plasma-assisted atomic layer deposition. The substrate is then subjected to thermal processing to activate and diffuse dopants into the substrate surface. | 06-30-2011 |
20110207307 | PLASMA IMMERSION ION IMPLANTATION METHOD USING A PURE OR NEARLY PURE SILICON SEASONING LAYER ON THE CHAMBER INTERIOR SURFACES - Plasma immersion ion implantation employing a very high RF bias voltage on an electrostatic chuck to attain a requisite implant depth profile is carried out by first depositing a partially conductive silicon-containing seasoning layer over the interior chamber surfaces prior to wafer introduction. | 08-25-2011 |
20110226617 | DIELECTRIC DEPOSITION USING A REMOTE PLASMA SOURCE - A sputter deposition system comprises a vacuum chamber including a vacuum pump for maintaining a vacuum in the vacuum chamber, a gas inlet for supplying process gases to the vacuum chamber, a sputter target and a substrate holder within the vacuum chamber, and a plasma source attached to the vacuum chamber and positioned remotely from the sputter target, the plasma source being configured to form a high density plasma beam extending into the vacuum chamber. The plasma source may include a rectangular cross-section source chamber, an electromagnet, and a radio frequency coil, wherein the rectangular cross-section source chamber and the radio frequency coil are configured to give the high density plasma beam an elongated ovate cross-section. Furthermore, the surface of the sputter target may be configured in a non-planar form to provide uniform plasma energy deposition into the target and/or uniform sputter deposition at the surface of a substrate on the substrate holder. The sputter deposition system may include a plasma spreading system for reshaping the high density plasma beam for complete and uniform coverage of the sputter target. | 09-22-2011 |
20110256691 | REMOVAL OF SURFACE DOPANTS FROM A SUBSTRATE - A method and apparatus for removing excess dopant from a doped substrate is provided. In one embodiment, a substrate is doped by surfaced deposition of dopant followed by formation of a capping layer and thermal diffusion drive-in. A reactive etchant mixture is provided to the process chamber, with optional plasma, to etch away the capping layer and form volatile compounds by reacting with excess dopant. In another embodiment, a substrate is doped by energetic implantation of dopant. A reactive gas mixture is provided to the process chamber, with optional plasma, to remove excess dopant adsorbed on the surface and high-concentration dopant near the surface by reacting with the dopant to form volatile compounds. The reactive gas mixture may be provided during thermal treatment, or it may be provided before or after at temperatures different from the thermal treatment temperature. The volatile compounds are removed. Substrates so treated do not form toxic compounds when stored or transported outside process equipment. | 10-20-2011 |
20110259268 | METHOD FOR MEASURING DOPANT CONCENTRATION DURING PLASMA ION IMPLANTATION - Embodiments of the invention generally provide apparatuses for endpoint detection of dopants. In one embodiment, the apparatus has a plasma chamber containing a body having sidewalls, a lid, and a bottom encompassing an interior volume and a substrate support assembly disposed within the body and having a substrate supporting surface configured to support a substrate. The apparatus also has a processing region disposed between the substrate supporting surface and a gas distribution assembly—which contains a perforated plate disposed above the substrate supporting surface. The apparatus also has a plasma source coupled with the body and configured to form an inductively coupled plasma within the interior region. Additionally, the apparatus has an optical sensor disposed either above or below the substrate supporting surface and coupled with a controller, wherein the controller is configured to derive a current dopant concentration relative to an amount of radiation received by the optical sensor. | 10-27-2011 |
20120302048 | PRE OR POST-IMPLANT PLASMA TREATMENT FOR PLASMA IMMERSED ION IMPLANTATION PROCESS - Methods for implanting ions into a substrate by a plasma immersion ion implanting process are provided. In one embodiment, the method for implanting ions into a substrate by a plasma immersion ion implantation process includes providing a substrate into a processing chamber, flowing a gas mixture including a hydride dopant gas and a fluorine-containing dopant gas into the processing chamber, wherein the hydride dopant gas comprises P-type hydride dopant gas, N-type hydride dopant gas, or a combination thereof, and the fluorine-containing dopant gas comprises a P-type or N-type dopant atom, generating a plasma from the gas mixture, and co-implanting ions from the gas mixture into a surface of the substrate. | 11-29-2012 |
20120325149 | GAS DISTRIBUTION SYSTEM - In some embodiments, a gas distribution system may include a body disposed within a through hole formed in a process chamber body, the body comprising an opening, wherein an outer surface of the body is disposed a first distance from an inner surface of the through hole to form a first gap; a flange disposed proximate a first end of the body, the flange having an outer dimension greater than an inner dimension of the through hole; a showerhead disposed proximate a second end of the body opposite the first end and extending outwardly from the body to overlap a portion of the process chamber body, the showerhead configured to allow a flow of gas to an inner volume of the process chamber, wherein an outer surface of the showerhead is disposed a second distance from an inner surface of the process chamber body to form a second gap. | 12-27-2012 |
20140017518 | PATTERNING OF MAGNETIC THIN FILM USING ENERGIZED IONS - A method for patterning a magnetic thin film on a substrate includes: providing a pattern about the magnetic thin film, with selective regions of the pattern permitting penetration of energized ions of one or more elements. Energized ions are generated with sufficient energy to penetrate selective regions and a portion of the magnetic thin film adjacent the selective regions. The substrate is placed to receive the energized ions. The portions of the magnetic thin film are rendered to exhibit a magnetic property different than selective other portions. A method for patterning a magnetic media with a magnetic thin film on both sides of the media is also disclosed. | 01-16-2014 |
20140038431 | APPARATUS AND METHODS FOR MICROWAVE PROCESSING OF SEMICONDUCTOR SUBSTRATES - Methods and apparatus for radiation processing of semiconductor substrates using microwave or millimeter wave energy are provided. The microwave or millimeter wave energy may have a frequency between about 600 MHz and about 1 THz. Alternating current from a magnetron is coupled to a leaky microwave emitter that has an inner conductor and an outer conductor, the outer conductor having openings with a dimension smaller than a wavelength of the emitted radiation. The inner and outer conductors are separated by an insulating material. Interference patterns produced by the microwave emissions may be uniformized by phase modulating the power to the emitter and/or by frequency modulating the frequency of the power itself. Power from a single generator may be divided to two or more emitters by a power divider. | 02-06-2014 |
20140071581 | PORTABLE ELECTROSTATIC CHUCK CARRIER FOR THIN SUBSTRATES - Embodiments of a portable electrostatic chuck for use in a substrate process chamber to support an ultra-thin substrate when disposed thereon are provided herein. In some embodiments, a portable electrostatic chuck may include a carrier comprising a dielectric material; an electrically conductive layer disposed on a top surface of the carrier; a dielectric layer disposed over the electrically conductive layer, such that the electrically conductive layer is disposed between the carrier and the dielectric layer; and at least one conductor coupled to the electrically conductive layer, wherein the portable electrostatic chuck is configured to electrostatically retain the ultra-thin substrate to the portable electrostatic chuck, wherein the portable electrostatic chuck is further configured to be handled and moved by substrate processing equipment outside of the substrate process chamber, and wherein the portable electrostatic chuck is sized to support large ultra-thin substrates. | 03-13-2014 |
20140083363 | PATTERNING OF MAGNETIC THIN FILM USING ENERGIZED IONS AND THERMAL EXCITATION - A method for patterning a magnetic thin film on a substrate includes: providing a pattern about the magnetic thin film, with selective regions of the pattern permitting penetration of energized ions of one or more elements. Energized ions are generated with sufficient energy to penetrate selective regions and a portion of the magnetic thin film adjacent the selective regions. The substrate is placed to receive the energized ions. The portion of the magnetic thin film is subjected to thermal excitation. The portions of the magnetic thin film are rendered to exhibit a magnetic property different than selective other portions. A method for patterning a magnetic media with a magnetic thin film on both sides of the media is also disclosed. | 03-27-2014 |
20140248759 | SAFE HANDLING OF LOW ENERGY, HIGH DOSE ARSENIC, PHOSPHORUS, AND BORON IMPLANTED WAFERS - A method of preventing toxic gas formation after an implantation process is disclosed. Certain dopants, when implanted into films disposed on a substrate, may react when exposed to moisture to form a toxic gas and/or a flammable gas. By in-situ exposing the doped film to an oxygen containing compound, dopant that is shallowly implanted into the layer stack reacts to form a dopant oxide, thereby reducing potential toxic gas and/or flammable gas formation. Alternatively, a capping layer may be formed in-situ over the implanted film to reduce the potential generation of toxic gas and/or flammable gas. | 09-04-2014 |