Entries |
Document | Title | Date |
20080217563 | MANUFACTURING METHOD OF SEMICONDUCTOR DEVICE AND SEMICONDUCTOR MANUFACTURING APPARATUS - The present invention is a semiconductor manufacturing apparatus by which an impurity can be introduced into an active layer at a low and a stable concentration in order to form semiconductor elements that have little variation in threshold voltage. In the semiconductor manufacturing apparatus that includes a washing unit; an impurity introduction unit used to attach the impurity to the surface of the semiconductor film; a laser crystallization unit used to crystallize the semiconductor film to which an impurity has been attached; and transfer robots, the amount of the impurity attached to the semiconductor film is controlled by the length of time of exposure of the substrate in the impurity introduction unit, and the semiconductor film is crystallized while a crystalline semiconductor film that contains an impurity at low concentration is formed simultaneously by laser crystallization. | 09-11-2008 |
20080230724 | Contamination reduction during ion implantation - A method includes generating an ion beam having ions at a first charge state, accelerating the ions at the first charge state to a final energy, altering the first charge state to a second charge state for some of said ions, the second charge state less than the first charge state, providing an ion beam having ions at the second charge state and parasitic beamlets having ions at a charge state different than the second charge state, directing the ion beam having ions at the second charge state towards a wafer, and directing the parasitic beamlets away from the wafer. An ion implanter having a charge exchange apparatus is also provided. | 09-25-2008 |
20080237496 | Techniques for Improving the Performance and Extending the Lifetime of an Ion Source with Gas Mixing - Techniques improving the performance and extending the lifetime of an ion source with gas mixing are disclosed. In one particular exemplary embodiment, the techniques may be realized as a method for improving performance and extending lifetime of an ion source in an ion implanter. The method may comprise introducing a predetermined amount of dopant gas into an ion source chamber. The dopant gas may comprise a dopant species. The method may also comprise introducing a predetermined amount of diluent gas into the ion source chamber. The diluent gas may dilute the dopant gas to improve the performance and extend the lifetime of the ion source. The diluent gas may further comprise a co-species that is the same as the dopant species. | 10-02-2008 |
20080245974 | METHOD OF INTRODUCING MATERIAL INTO A SUBSTRATE BY GAS-CLUSTER ION BEAM IRRADIATION - Method of infusing or introducing material into a substrate using a gas cluster ion beam. The method includes maintaining a reduced-pressure environment around a substrate holder and holding a substrate securely within that reduced-pressure environment. A gas-cluster ion beam formed from a pressurized gas mixture including an inert gas and at least one other atomic or molecular specie is provided to the reduced-pressure environment and accelerated. In one embodiment, the method includes irradiating the accelerated gas-cluster ion beam onto one or more surface portions of the substrate to form an infused region or gas-cluster ion-impact region therein by introducing part or all of the atomic or molecular specie into the surface. In another embodiment, the method includes modifying at least one electrical property of the surface of the substrate by irradiating the accelerated gas-cluster ion beam onto one or more surface portions of the substrate. | 10-09-2008 |
20080251737 | ION IMPLANTATION APPARATUS - A beam line before incidence on a beam scanner is arranged with an injector flag Faraday cup that detects a beam current by measuring a total beam amount of an ion beam to be able to be brought in and out thereto and therefrom. When the ion beam is shut off by placing the injector flag Faraday cup on a beam trajectory line, the ion beam impinges on graphite provided at the injector flag Faraday cup. At this occasion, even when the graphite is sputtered by the ion beam, since the injector flag Faraday cup is arranged on an upstream side of the beam scanner and the ion beam is shut off by the injector flag Faraday cup, particles of the sputtered graphite do not adhere to a peripheral member of the injector flag Faraday cup. | 10-16-2008 |
20080258084 | Charged-Particle Exposure Apparatus - A particle-beam projection processing apparatus for irradiating a target, with an illumination system for forming a wide-area illuminating beam of energetic electrically charged particles; a pattern definition means for positioning an aperture pattern in the path of the illuminating beam; and a projection system for projecting the beam thus patterned onto a target to be positioned after the projection system. A foil located across the path of the patterned beam is positioned between the pattern definition means and the position of the target at a location close to an image of the aperture pattern formed by the projection system. | 10-23-2008 |
20080265180 | Ion beam inspection apparatus, ion beam inspecting method, semiconductor manufacturing apparatus, and ion source apparatus - The central axis of a source head and an extraction electrode is aligned on a line, and confirmed by a laser beam whether the line is coaxial with the ion beam axis. Thus, a light emitting unit that emits the laser beam on the ion beam axis is fitted to a housing instead of the source head, and a reflector that reflects the laser beam is fitted to the extraction electrode. A light emitting apparatus also has a function of detecting the laser beam to detect the laser beam that is reflected by the reflector, and sends the intensity of the detected laser beam to a control unit. The extraction electrode is positionally adjusted so that the intensity of the laser beam becomes maximum, whereby the ion beam axis can coincide with the central axes of the ion source and the extraction electrode. | 10-30-2008 |
20080277597 | REMOVABLE LINERS FOR CHARGED PARTICLE BEAM SYSTEMS - An apparatus. The apparatus including: a chamber having an interior surface; a pump port for evacuating the chamber; a substrate holder within the chamber; a charged particle beam within the chamber, the charged beam generated by a source and the charged particle beam striking the substrate; and one or more liners in contact with one or more different regions of the interior surface of the chamber, the liners preventing material generated by interaction of the charged beam and the substrate from coating the one or more different regions of the interior surface of the chamber. | 11-13-2008 |
20080283777 | IN-SITU HIGH-RESOLUTION LIGHT-OPTICAL CHANNEL FOR OPTICAL VIEWING AND SURFACE PROCESSING IN PARALLEL WITH CHARGED PARTICLE (FIB AND SEM) TECHNIQUES - An apparatus for simultaneous parallel processing of a sample using light energy for optical viewing or surface processing in parallel with a charged particle beam. A charged particle beam transmits a focused ion beam or an electron beam along a path to a sample. An optical microscope transmits light along a first path to the sample, and a prism aligned along the first light path reflects light into a second light path toward the sample. A portion of the prism and reflective surface is removed for passage of the charged particle beam. A lens is aligned along the second light path and has a portion removed for passage of the charged particle beam. The removed portions of the prism and lens are aligned along the charged particle beam path to permit parallel delivery of the charged particle beam and the light to substantially the same portion of the sample. | 11-20-2008 |
20080283778 | Apparatus for ion beam fabrication - The apparatus for ion beam fabrication, which has been able to detect any anomalous condition of ion beams only by means of the current irradiated on the specimen, could not compensate the failure by investigating the cause and could not realize stable processing. To solve the problem described above, the present invention includes the first and second blankers and Faraday cups switches ON and OFF the first and second blankers and monitors beam current at two positions above and below the projection mask. By adopting this configuration, it will be possible to acquire the information on failure in ion beam, sort out the cause of the failure and to compensate the failure while limiting damages to the projection mask. As a result, it will be possible to realize stable processing by means of ion beam, and to use the ion beam fabricating device on a stable basis. | 11-20-2008 |
20080296516 | METHOD AND APPARATUS FOR SPECIMEN FABRICATION - A specimen fabrication apparatus, including: an ion beam irradiating optical system to irradiate a sample placed in a chamber with an ion beam; a specimen holder to mount a specimen separated by the irradiation with the ion beam; a holder cassette to hold the specimen holder; a sample stage to hold, the sample and the holder cassette; and a probe to move the specimen to the specimen holder, wherein the holder cassette is transferred to outside of the chamber in a condition of holding the specimen holder with the specimen mounted. | 12-04-2008 |
20080302979 | Working Method by Focused Ion Beam and Focused Ion Beam Working Apparatus - Even in a case where it is one whose size is smaller than an irradiation width of a focused ion beam, it is possible to desirably work its place desired to be worked. | 12-11-2008 |
20080315129 | Ion planting while growing a III-nitride layer - A method that includes implantation of dopants while a III-nitride body is being grown on a substrate, and an apparatus for the practice of the method. | 12-25-2008 |
20080315130 | FOCUSED ION BEAM PROCESSING SYSTEM AND METHOD - A focused ion beam (FIB) processing system includes a FIB irradiation unit that irradiates a FIB onto a pattern formed in a wafer, to form a section of the pattern, an imaging unit that images the section of the pattern, a calculation unit that calculates a pattern size based on the image of the section, a judgment unit that judges whether or not a differential of the pattern size with respect to time is equal to or below a threshold; and a control unit that stops the FIB irradiation unit if the judgment unit judges that the differential of the pattern size is equal to or below the threshold. | 12-25-2008 |
20090001291 | Apparatus and Method for Partial Ion Implantation - An apparatus and method for partial ion implantation, which desirably provide control over the energy of the implanted dopants, generally includes an ion beam generator, and first and second deceleration units. The first deceleration unit decelerates the energy of an ion beam generated by the ion beam generator; and a subsequent, second deceleration unit further decelerates the energy into different energy levels according to regions of a wafer into which the ions are to be implanted. | 01-01-2009 |
20090008577 | Conformal Doping Using High Neutral Density Plasma Implant - A plasma doping apparatus includes a plasma source that generates a pulsed plasma. A platen supports a substrate proximate to the plasma source for plasma doping. A structure absorbs a film which provides a plurality of neutrals when desorbed. A bias voltage power supply generates a bias voltage waveform having a negative potential that attracts ions in the plasma to the substrate for plasma doping. A radiation source irradiates the film absorbed on the structure, thereby desorbing the film and generating a plurality of neutrals that scatter ions from the plasma while the ions are being attracted to the substrate, thereby performing conformal plasma doping. | 01-08-2009 |
20090008578 | METHOD AND APPARATUS FOR SPECIMEN FABRICATION - A specimen fabrication apparatus, including: an ion beam irradiating optical system to irradiate a sample placed in a chamber, with an ion beam; a specimen holder to mount a specimen separated by the irradiation with the ion beam; a holder cassette to hold the specimen holder; a sample stage to hold the sample and the holder cassette; and a probe to move the specimen to the specimen holder, wherein the holder cassette is transferred to outside of the chamber in a condition of holding the specimen holder with the specimen mounted. | 01-08-2009 |
20090014667 | EXTERNAL CATHODE ION SOURCE - An ion source is disclosed for use in fabrication of semiconductors. The ion source includes an electron emitter that includes a cathode mounted external to the ionization chamber for use in fabrication of semiconductors. In accordance with an important aspect of the invention, the electron emitter is employed without a corresponding anode or electron optics. As such, the distance between the cathode and the ionization chamber can be shortened to enable the ion source to be operated in an arc discharge mode or generate a plasma. Alternatively, the ion source can be operated in a dual mode with a single electron emitter by selectively varying the distance between the cathode and the ionization chamber. | 01-15-2009 |
20090026390 | TECHNIQUES FOR PLASMA INJECTION - Techniques for plasma injection for space charge neutralization of an ion beam are disclosed. In one particular exemplary embodiment, the techniques may be realized as a plasma injection system for space charge neutralization of an ion beam. The plasma injection system may comprise a first array of magnets and a second array of magnets positioned along at least a portion of an ion beam path, the first array being on a first side of the ion beam path and the second array being on a second side of the ion beam path, the first side opposing the second side. At least two adjacent magnets in the first array of magnets may have opposite polarity. The plasma injection system may also comprise a plasma source configured to generate a plasma in a region associated with a portion of the ion beam path by colliding at least some electrons with a gas. | 01-29-2009 |
20090050825 | Sealing between vacuum chambers - A sealing system is disclosed. One such sealing system includes a first vacuum chamber and a second vacuum chamber. The sealing system includes a first sealing unit having a proximal end and a distal end, the proximal end of the first sealing unit disposed on the first vacuum chamber. The sealing system includes a second sealing unit having a distal end and a proximal end, the distal end of the second sealing unit disposed on the distal end of the first sealing unit and the proximal end of the second sealing unit disposed on the second vacuum chamber. One of the sealing units is concave, while the other is convex. The sealing system also includes a first o-ring, a second o-ring, and a third o-ring. | 02-26-2009 |
20090057572 | Terminal Structures Of An Ion Implanter Having Insulated Conductors With Dielectric Fins - Terminal structures of an ion implanter having insulated conductors with dielectric fins are disclosed. In one particular exemplary embodiment, the terminal structures of an ion implanter may be realized with insulated conductors with one or more dielectric fins. For example, the ion implanter may comprise an ion source configured to provide an ion beam. The ion implanter may also comprise a terminal structure defining a cavity, wherein the ion source may be at least partially disposed within the cavity. The ion implanter may further comprise an insulated conductor having at least one dielectric fin disposed proximate an exterior portion of the terminal structure to modify an electric field. | 03-05-2009 |
20090057573 | TECHNIQUES FOR TERMINAL INSULATION IN AN ION IMPLANTER - Techniques for terminal insulation for an ion implanter are disclosed. In one particular exemplary embodiment, the techniques may be realized as an ion implanter comprising a terminal structure defining a terminal cavity. The ion implanter may also comprise a grounded enclosure defining a grounded cavity and the terminal structure may be at least partially disposed within the grounded cavity. The ion implanter may further comprise an intermediate terminal structure disposed proximate an exterior portion of the terminal structure and at least partially disposed within the grounded cavity. | 03-05-2009 |
20090057574 | METHODS FOR MODIFYING FEATURES OF A WORKPIECE USING A GAS CLUSTER ION BEAM - Embodiments of methods of modifying surface features on a workpiece with a gas cluster ion beam are generally described herein. Other embodiments may be described and claimed. | 03-05-2009 |
20090072163 | TECHNIQUES FOR CONTROLLING A CHARGED PARTICLE BEAM - Techniques for controlling a charged particle beam are disclosed. In one particular exemplary embodiment, the techniques may be realized as a charged particle acceleration/deceleration system. The charged particle acceleration/deceleration system may comprise an acceleration column. The acceleration column may comprise a plurality of electrodes having apertures through which a charged particle beam may pass. The charged particle acceleration/deceleration system may also comprise a plurality of resistors electrically coupled to the plurality of electrodes. The charged particle acceleration/deceleration system may further comprise a plurality of switches electrically coupled to the plurality of electrodes and the plurality of resistors, each of the plurality of switches may be configured to be selectively switched respectively in a plurality of operation modes. | 03-19-2009 |
20090072164 | ION IMPLANTING APPARATUS - An ion implanter for manufacturing a single crystal film by extracting a hydrogen ion or a rare-gas ion from an ion source, selects a desired ion with a first sector electromagnet, scanning the ion with a scanner, collimates the ion with a second sector electromagnet, and implants it into a substrate; the ion source is configured to be located close to the entrance side focal point of the first sector electromagnet. In this case, when an aperture of an extraction section of the ion source is circular and entrance side focal points in a deflection surface and a surface perpendicular thereto in the first sector electromagnet are coincident, the ion beam after passing the first sector electromagnet becomes completely parallel in the two surfaces and the spot shape becomes a circle. | 03-19-2009 |
20090084988 | SINGLE WAFER IMPLANTER FOR SILICON-ON-INSULATOR WAFER FABRICATION - An ion implanter is disclosed. One such ion implanter includes an ion beam source configured to generate oxygen, nitrogen, helium, or hydrogen ions into an ion beam with a specific dose range, and an analyzer magnet configured to remove undesired species from the ion beam. The ion implanter includes an electrostatic chuck having a backside gas thermal coupling that is configured to hold a single workpiece for silicon-on-insulator implantation by the ion beam and is configured to cool the workpiece to a temperature in a range of approximately 300° C. to 600° C. | 04-02-2009 |
20090090876 | IMPLANT BEAM UTILIZATION IN AN ION IMPLANTER - To select a scan distance to be used in scanning a wafer with an implant beam, a dose distribution along a first direction is calculated based on size or intensity of the implant beam and a scan distance. The scan distance is the distance measured in the first direction between a first path and a final path of the implant beam scanning the wafer along a second direction in multiple paths. A relative velocity profile along the second direction is determined based on the dose distribution. Dose uniformity on the wafer is calculated based on the wafer being scanned using the relative velocity profile and the determined dose distribution. The scan distance is adjusted and the preceding steps are repeated until the calculated dose uniformity meets one or more uniformity criteria. | 04-09-2009 |
20090095923 | INSTALLATION AND METHOD OF NANOFABRICATION - Nanofabrication installation comprising: a specimen holder, for holding a specimen; a mask, having a through-opening between the upper and lower faces of the mask, for letting charged particles through onto the specimen holder; a near-field detection device for detecting a relative position between the mask ( | 04-16-2009 |
20090114853 | MANUFACTURING SYSTEM FOR SEMICONDUCTOR DEVICE CAPABLE OF CONTROLLING VARIATION IN ELECTRICAL PROPERTY OF ELEMENT IN WAFER SURFACE AND METHOD FOR MANUFACTURING THE SEMICONDUCTOR DEVICE - A measuring device measures a gate length of a plurality of gate electrodes formed on a wafer. A calculation device calculates data of an ion implantation dosage for making uniform a threshold voltage in a wafer surface on the basis of distribution of the gate length in a wafer surface measured by the measuring device. The ion implantation device implants ions into the wafer on the basis of the data of the ion implantation dosage calculated by the calculation device. | 05-07-2009 |
20090166564 | METHODS FOR MONITORING IMPLANTER PERFORMANCE - Methods are presented to monitor the performance of an ion implanter such as the E500. Ion implantation typically involves physical processes performed on a wafer such as rotation, tilt, and twist. These methods generate particulate contaminants (PCs) that affect the kill rate of the semiconductor devices on the wafer. Variations in tilt angle also compromise dose accuracy. Presently, methods for testing for PCs and implant dose accuracy do not simulate actual manufacturing conditions. This invention discloses methods to test PC buildup using multiple wafers that are subjected to rotation, twist, tilt, and combinations thereof. Additionally, methods to test dose accuracy are presented, involving implanting a monitor wafer at an angle where the crystalline channel is aligned with the ion beam. Measuring sheet resistance as a function of tilt angle at this point ensures accurate tilt-angle calibration of the ion implanter. | 07-02-2009 |
20090166565 | Ion implanters - The present invention relates to components in an ion implanter that may see incidence of the ion beam, such as a beam dump or a beam stop. Such components will be prone to the ions sputtering material from their surfaces, and sputtered material may become entrained in the ion beam. This entrained material is a source of contamination. The present invention provides such components with a chamber having an elongate slot opening defined by edges, and operating the ion implanter such that a central portion of the ion beam enters the component through the opening with the edges clipping at least a peripheral portion of the ion beam. The arrangement mitigates the problem of sputtered material escaping back out from the component and becoming entrained in the ion beam. | 07-02-2009 |
20090166566 | High tilt implant angle performance using in-axis tilt - The present invention comprises a method for high tilt angle implantation, with angular precision not previously achievable. An ion beam, having a width and height dimension, is made up of a number of individual beamlets. These beamlets typically display a higher degree of parallelism in one of these two dimensions. Thus, to minimize angular error, the workpiece is tilted about an axis substantially perpendicular to the dimension having the higher degree of parallelism. The workpiece is then implanted at a high tilt angle and rotated about a line orthogonal to the surface of the workpiece. This process can be repeated until the high tilt implantation has been performed in all required regions. | 07-02-2009 |
20090166567 | METHOD OF PERFORMING ION IMPLANTATION - A method of performing an ion implantation is provided. A workpiece is installed in the ion implanter. A wafer is provided in a receiving space within an ion implanter. An ion beam is generated by an ion source of the ion implanter. The bombard of the ion beam is blocked and particles generated during or after conducting the step of generating the ion beam are collected by the workpiece. | 07-02-2009 |
20090173894 | Ion implanters - The present invention relates to components in an ion implanter that may see incidence of the ion beam, such as a beam dump or a beam stop. Such components will be prone to the ions sputtering material from their surfaces, and sputtered material may become entrained in the ion beam. This entrained material is a source of contamination. The present invention provides an ion implanter comprising power supply apparatus and an ion-receiving component. The component has an opening that receives ions from an ion beam such that ions strike an internal surface. The power supply apparatus is arranged to provide an electrical bias to the internal surface to decelerate the ions prior to their striking the surface, thereby mitigating the problem of material being sputtered from the surface. | 07-09-2009 |
20090189096 | APPARATUS AND METHODS FOR ION BEAM IMPLANTATION USING RIBBON AND SPOT BEAMS - An ion implantation apparatus with multiple operating modes is disclosed. The ion implantation apparatus has an ion source and an ion extraction means for extracting a ribbon-shaped ion beam therefrom. The ion implantation apparatus includes a magnetic analyzer for selecting ions with specific mass-to-charge ratio to pass through a mass slit to project onto a substrate. Multipole lenses are provided to control beam uniformity and collimation. A two-path beamline in which a second path incorporates a deceleration or acceleration system incorporating energy filtering is disclosed. Finally, methods of ion implantation are disclosed in which the mode of implantation may be switched from one-dimensional scanning of the target to two-dimensional scanning. | 07-30-2009 |
20090200493 | METHODS FOR IN SITU SURFACE TREATMENT IN AN ION IMPLANTATION SYSTEM - A system and methods are provided for mitigating or removing workpiece surface contaminants or conditions. Methods of the invention provide treatment of the wafer surface to provide a known surface condition. The surface condition can then be maintained during and following implantation of the workpiece surface with a dopant. | 08-13-2009 |
20090200494 | TECHNIQUES FOR COLD IMPLANTATION OF CARBON-CONTAINING SPECIES - Techniques for cold implantation of carbon-containing species are disclosed. In one particular exemplary embodiment, the techniques may be realized as an apparatus for ion implantation including a cooling device for cooling a target material to a predetermined temperature, and an ion implanter for implanting the target material with a carbon-containing species at the predetermined temperature to improve at least one of strain and amorphization. | 08-13-2009 |
20090206281 | VAPOR DELIVERY SYSTEM USEFUL WITH ION SOURCES AND VAPORIZERS FOR USE IN SUCH SYSTEM - Vapor delivery systems and methods that control the heating and flow of vapors from solid feed material, especially material that comprises cluster molecules for semiconductor manufacture. The systems and methods safely and effectively conduct the vapor to a point of utilization, especially to an ion source for ion implantation. Ion beam implantation is shown employing ions from the cluster materials. The vapor delivery system includes reactive gas cleaning of the ion source, control systems and protocols, wide dynamic range flow-control systems and vaporizer selections that are efficient and safe. Borane, decarborane, carboranes, carbon clusters and other large molecules are vaporized for ion implantation. Such systems are shown cooperating with novel vaporizers, ion sources, and reactive cleaning systems. | 08-20-2009 |
20090230329 | ION IMPLANTATION METHOD - An ion implantation method is provided. The method, before ion implanting, is to rotate the substrate by an angle and shift the scan path of the ion beam with an interlace pitch in the direction perpendicular to the scan direction and on the plane of the substrate. Therefore a plurality of interlaced and not overlapped ion implantation scan lines are formed on the surface of the substrate, so the method can enhance the uniformity of the dose of the ion implantation in the substrate. | 09-17-2009 |
20090236547 | EXTRACTION ELECTRODE SYSTEM FOR HIGH CURRENT ION IMPLANTER - A system and method extraction electrode system, comprising an extraction electrode, wherein the extraction electrode, further defines an aperture and forms a portion of the outside wall of the ion source and is configured to extract ions from the ion source, a suppression disk half assembly comprising two suppression electrode plate disk halves that form a variable suppression aperture, a ground disk half assembly comprising two ground electrode plate disk halves that form an variable ground aperture, wherein the suppression disk half assembly is configured between the extraction electrode and the ground disk half assembly, wherein the suppression aperture and the ground aperture variable in the direction perpendicular to the ion beam direction of travel, and wherein the extraction electrode system is used with a pendulum reciprocating drive apparatus. | 09-24-2009 |
20090242808 | TECHNIQUES FOR IMPROVED UNIFORMITY TUNING IN AN ION IMPLANTER SYSTEM - Techniques for uniformity tuning in an ion implanter system are disclosed. In one particular exemplary embodiment, the techniques may be realized as a method for ion beam uniformity tuning. The method may comprise generating an ion beam in an ion implanter system. The method may also comprise measuring a first ion beam current density profile along an ion beam path. The method may further comprise measuring a second ion beam current density profile along the ion beam path. In addition, the method may comprise determining a third ion beam current density profile along the ion beam path based at least in part on the first ion beam current density profile and the second ion beam current density profile. | 10-01-2009 |
20090267001 | LOW CONTAMINATION, LOW ENERGY BEAMLINE ARCHITECTURE FOR HIGH CURRENT ION IMPLANTATION - An ion implantation system comprising an ion source that generates an ion beam along a beam path, a mass analyzer component downstream of the ion source that performs mass analysis and angle correction on the ion beam, a resolving aperture electrode comprising at least one electrode downstream of the mass analyzer component and along the beam path having a size and shape according to a selected mass resolution and a beam envelope, a deflection element downstream of the resolving aperture electrode that changes the path of the ion beam exiting the deflection element, a deceleration electrode downstream of the deflection element that decelerates the ion beam, a support platform within an end station for retaining and positioning a workpiece which is implanted with charged ions, and wherein the end station is mounted approximately eight degrees counterclockwise so that the deflected ion beam is perpendicular to the workpiece. | 10-29-2009 |
20090267002 | Apparatus and Method for Partial Ion Implantation Using Atom Vibration - A partial ion implantation apparatus and method are provided. The partial ion implantation apparatus includes an ion beam generator, a wafer chuck, and a plurality of atom-vibrating devices. The ion beam generator is configured to generate an ion beam. The wafer chuck is disposed to support a wafer into which the ion beam is implanted. The atom-vibrating devices are configured to vibrate silicon atoms in the wafer. | 10-29-2009 |
20090272918 | SYSTEM AND METHOD OF PERFORMING UNIFORM DOSE IMPLANTATION UNDER ADVERSE CONDITIONS - An ion implantation system and associated method includes a scanner configured to scan a pencil shaped ion beam into a ribbon shaped ion beam, and a beam bending element configured to receive the ribbon shaped ion beam having a first direction, and bend the ribbon shaped ion beam to travel in a second direction. The system further includes an end station positioned downstream of the beam bending element, wherein the end station is configured to receive the ribbon shaped ion beam traveling in the second direction, and secure a workpiece for implantation thereof. In addition, the system includes a beam current measurement system located at an exit opening of the beam bending element that is configured to measure a beam current of the ribbon shaped ion beam at the exit opening of the beam bending element. | 11-05-2009 |
20090278059 | APPARATUS FOR DETECTING FILM DELAMINATION AND A METHOD THEREOF - A method and apparatus are described herein which allow the progression of delamination of a film to be monitored. An interferometer is used to detect the onset and progression of thin film delamination. By projecting one or more wavelengths at a surface, and measuring the reflectance of these projected wavelengths, it is possible to monitor the progression of the delamination process. Testing has shown that different stages of the delamination process produce different reflectance graphs. This information can be used to establish implantation parameters, or can be used as an in situ monitor. The same techniques can be used for other applications. For example, in certain implantation systems, such as PECVD, a film of material may developed on the walls of the chamber. The techniques described herein can be used to monitor this separation, and determine when preventative maintenance may be performed on the chamber. | 11-12-2009 |
20090283705 | ION IMPLANTER FOR PHOTOVOLTAIC CELL FABRICATION - Ion implanters are especially suited to meet process dose and energy demands associated with fabricating photovoltaic devices by ion implantation followed by cleaving. | 11-19-2009 |
20090294698 | CONTROL OF PARTICLES ON SEMICONDUCTOR WAFERS WHEN IMPLANTING BORON HYDRIDES - A method for reducing particle contamination during implantation of ions comprises providing an implantation system for implanting ions into a workpiece via an ion beam, wherein one or more components are under selective vacuum and have one or more contaminants in a first state disposed thereon. A gas is introduced to the implantation system, wherein the gas generally reacts with at least a portion of the one or more contaminants, therein transforming the at least a portion of the one or more contaminants into a second state The at least a portion of the one or more contaminants in the second state remain disposed on the one or more components, and wherein the at least a portion of the second state of the one or more contaminants generally does not produce particle contamination on the one or more workpieces. | 12-03-2009 |
20090314962 | METHOD AND APPARATUS FOR CONTROLLING BEAM CURRENT UNIFORMITY IN AN ION IMPLANTER - An electrode assembly for use with an ion source chamber or as part of an ion implanter processing system to provide a uniform ion beam profile. The electrode assembly includes an electrode having an extraction slot with length L aligned with an aperture of the ion source chamber for extracting an ion beam. The electrode includes a plurality of segments partitioned within the length of the extraction slot where each of the segments is configured to be displaced in at least one direction with respect to the ion beam. A plurality of actuators are connected to the plurality of electrode segments for displacing one or more of the segments. By displacing at least one of the plurality of electrode segments, the current density of a portion of the ion beam corresponding to the position of the segment within the extraction slot is modified to provide a uniform current density beam profile associated with the extracted ion beam. | 12-24-2009 |
20090314963 | METHOD FOR FORMING TRENCH ISOLATION - A method for treating a dielectric material using a gas cluster ion beam (GCIB) is described, and more particularly, a method for infusing material into a dielectric layer using a GCIB is described. The method comprises: filling a trench at least partially with a dielectric material; generating a GCIB; and irradiating the dielectric material with the GCIB to introduce one or more species into the dielectric material to a pre-determined depth. | 12-24-2009 |
20090314964 | ION-IMPLANTING APPARATUS - An ion-implanting apparatus comprising a holding unit that holds at least a semiconductor wafer and swings the wafer along a circular orbit, wherein an ion-beam is irradiated to a region that overlaps a part of the circular orbit; the holding unit comprises three or more holding pins that hold the wafer; the holding pins include a first type holding pin at least a portion of which being in contact with an edge of the wafer is made of a material selected from a thermo-setting resin and a photo-setting resin, and a second type holding pin at least a portion of which being in contact with the wafer is made of a material that contains graphite; and the first type holding pin of the plurality of holding pins is placed at a tail end position with respect to a direction of swinging the wafer. | 12-24-2009 |
20100006779 | ION IMPLANTATION APPARATUS AND ION IMPLANTATION METHOD - This ion implantation apparatus is provided with a holding devise which holds the wafer, and which turns it along its circumference. In addition to holding the wafer at a prescribed position, the ion implantation apparatus subjects the wafer to ion implantation in regions where there is partial overlap of its circumference. The holding devise turns and inclines the wafer, and also holds the wafer by three or more holding pins. The side face of the holding pin has an inversely tapered shape, and the multiple holding pins include a first holding pin whose protrusion amount is relatively small, and a second holding pin whose protrusion amount is relatively large. The holding pin which is on the upper side from the center of the wafer in the planar direction of the inclined wafer is the second holding pin, and the angle of inclination of the side face of the second holding pin at a position where ions are implanted into the wafer has an angular degree which is equal to or less than an angle of incidence of the ion beam relative to the wafer. | 01-14-2010 |
20100012861 | METHOD AND APPARATUS FOR MEASUREMENT OF BEAM ANGLE IN ION IMPLANTATION - An ion beam angle detection apparatus, comprising a linear drive assembly fixedly attached to a moveable profiler assembly, wherein the profiler assembly comprises, a profiler having a profiler aperture formed within a profiler top plate and a profiler sensor assembly, a moveable angle mask assembly comprising a moveable angle mask with a mask aperture, wherein the angle mask assembly is non-fixedly attached to the profiler assembly, the mask aperture is movable relative to the profiler aperture by energizing an mask linear drive fixedly attached to the profiler assembly and the profiler aperture is movable through a length greater than the elongated length of the ion beam. | 01-21-2010 |
20100025597 | ION IMPLANTING DEVICE AND METHOD - To reduce the occurrence of stripes in the oscillation direction of a semiconductor wafer which might occur when ion implantation scanning is performed by radiating ions onto the semiconductor wafer while oscillating the semiconductor wafer like a pendulum, the ion implantation of the present invention involves radiating ions while rotating a plurality of semiconductor wafers | 02-04-2010 |
20100044595 | Race track configuration and method for wafering silicon solar substrates - A system for manufacturing free-standing films from work pieces. The system includes a racetrack structure being configured to transfer at least one work piece and one or more accelerator-based ion implanters coupled to the racetrack structure via an end station. Each of the accelerator-based ion implanters is configured to introduce particles having an energy of greater than 1 MeV to implant into a surface of the work piece loaded in the end station to form a cleave region in the work piece. The system includes one or more cleave modules coupled to the racetrack structure configured to perform a cleave process to release a free-standing film from the work piece along the cleave region. Additionally, the system includes an output port coupled to each cleave module to output the free standing film detached from the work piece and one or more service modules each connected to the racetrack structure. | 02-25-2010 |
20100065761 | ADJUSTABLE DEFLECTION OPTICS FOR ION IMPLANTATION - A deflection component suitable for use in an ion implantation system comprises multiple electrodes that can be selectively biased to cause an ion beam passing therethrough to bend, deflect, focus, converge, diverge, accelerate, decelerate, and/or decontaminate. Since the electrodes can be selectively biased, and thus one or more of them can remain unbiased or off, the effective length of the beam path can be selectively adjusted as desired (e.g., based upon beam properties, such as energy, dose, species, etc.). | 03-18-2010 |
20100072401 | HYDROGEN ION IMPLANTER USING A BROAD BEAM SOURCE - Ion implanters incorporating multibeam ion sources are used to meet process dose and energy demands associated with fabricating a thin lamina for use in photovoltaic devices. The thin lamina are formed by ion implantation followed by cleaving. | 03-25-2010 |
20100072402 | EXTRACTION ELECTRODE MANIPULATOR - An extraction electrode manipulator system, comprising an ion source, a suppression electrode and a ground electrode, wherein the two electrode are supported by coaxially arranged two water cooled support tubes. A high voltage insulator ring is located on the other end of the coaxial support tube system to act as a mechanical support of the inner tube and also as a high voltage vacuum feedthrough to prevent sputtering and coating of the insulating surface. | 03-25-2010 |
20100084579 | FLUID DELIVERY MECHANISM FOR VACUUM WAFER PROCESSING SYSTEM - The fluid delivery mechanism of the present disclosure provides a solution for use in a single axis of motion that allows the connection of one or more fluid flow paths over a wide range of temperatures into a vacuum environment. The mechanism does not employ flexible tubing that is prone to fatigue, especially at very low temperatures. In one embodiment, a tube is axially moved within a sealed piston to allow for fluid delivery. In a second embodiment, bellows are used to provide the required functionality. In another embodiment, it is possible to achieve movement in two or more axis of motion by utilizing two or more appropriately configured mechanisms. | 04-08-2010 |
20100084580 | THERMAL MODULATION OF IMPLANT PROCESS - A method for ion implantation is disclosed which includes modulating the temperature of the substrate during the implant process. This modulation affects the properties of the substrate, and can be used to minimize EOR defects, selectively segregate and diffuse out secondary dopants, maximize or minimize the amorphous region, and vary other semiconductor parameters. In one particular embodiment, a combination of temperature modulated ion implants are used. Ion implantation at higher temperatures is used in sequence with regular baseline processing and with ion implantation at cold temperatures. The temperature modulation could be at the beginning or at the end of the process to alleviate the detrimental secondary dopant effects. | 04-08-2010 |
20100084581 | IMPLANT UNIFORMITY CONTROL - An apparatus and method for ion implantation that include destabilizing the ion beam as it passes through magnetic field, preferably a dipole magnetic field is disclosed. By introducing a bias voltage at certain points within the magnetic field, electrons from the plasma are drawn toward the magnet, thereby causing the ion beam to expand due to space charge effects. The bias voltage can be introduced into the magnet in a region where the magnetic field has only one component. Alternatively, the bias voltage can be in a region wherein the magnetic field has two components. | 04-08-2010 |
20100084582 | METHOD AND APPARATUS FOR CONTROLLING BEAM CURRENT UNIFORMITY IN AN ION IMPLANTER - An ion implantation system for neutralizing the space charge effect associated with a high current low energy ion beam. The implantation system includes an ion source configured to receive a dopant gas and generate ions having a particular energy and mass from which ions are extracted through an aperture. A work piece positioned downstream of the ion source for receiving the extracted ions in the form of an ion beam. A bleed gas channel disposed between the ion source and the work piece. The bleed gas channel supplying a gas used to neutralize the space charge effect associated with the ion beam. | 04-08-2010 |
20100084583 | REDUCED IMPLANT VOLTAGE DURING ION IMPLANTATION - A method for ion implantation is disclosed which includes decreasing the implant energy level as the implant process is ongoing. In this way, either a box-like profile or a profile with higher retained dose can be achieved, enabling enhanced activation at the same junction depth. In one embodiment, the initial implant energy is used to implant about 25% of the dose. The implant energy level is then reduced and an additional 50% of the dose is implanted. The implant energy is subsequently decreased again and the remainder of the dose is implanted. The initial portion of the dose can optionally be performed at cold, such as cryogenic temperatures, to maximize amorphization of the substrate. | 04-08-2010 |
20100084584 | ION IMPLANTING APPARATUS - An illuminating device includes: a light source which is disposed outside a vacuum chamber; a light guide which guides the light emitted from the light source, into the vacuum chamber; a light projecting portion which is fixed in the vacuum chamber, and which emits the light guided by the light guide; a light receiving portion which is attached to a support table of a holder driving device, and which receives the light emitted from the light projecting portion in a state where a holder is positioned in a notch detecting position; a light guide which guides the light received by the light receiving portion; and a light emitting device which is attached to the support table, and which irradiates an outer circumferential portion of a substrate with the light guided by the light guide. | 04-08-2010 |
20100140508 | COATED GRAPHITE LINERS - Liner elements designed to protect the components located in the beam line are disclosed. These liner elements, preferably constructed from graphite, are coated with a non-metal material, such as silicon, silicon carbide or diamond like carbon. These coatings significantly reduce the loose particles created by the liner. Therefore, following preventative maintenance, the ion implantation system can return to normal operation sooner. A method of providing preventative maintenance for an ion implanter is also disclosed, whereby used liners are cleaned and recoated before being used again. | 06-10-2010 |
20100155623 | ION IMPLANTATION WITH DIMINISHED SCANNING FIELD EFFECTS - Ion implantation systems and scanning systems are provided, in which a focus adjustment component is provided to adjust a focal property of an ion beam to diminish zero field effects of the scanner upon the ion beam. The focal property may be adjusted in order to improve the consistency of the beam profile scanned across the workpiece, or to improve the consistency of the ion implantation across the workpiece. Methods are disclosed for providing a scanned ion beam to a workpiece, comprising scanning the ion beam to produce a scanned ion beam, adjusting a focal property of an ion beam in relation to zero field effects of the scanner upon the ion beam, and directing the ion beam toward the workpiece. | 06-24-2010 |
20100155624 | FOCUSED ION BEAM APPARATUS, SAMPLE PROCESSING METHOD USING THE SAME, AND COMPUTER PROGRAM FOR FOCUSED ION BEAM PROCESSING - A focused ion beam apparatus includes: a focused ion beam irradiating mechanism configured to irradiate a sample with a focused ion beam; a detector configured to detect a secondary charged particle generated by irradiating the sample with the focused beam; an image generating unit configured to generate an sample image of the sample; a processing area setting unit configured to set a processing area image including a plurality of pixels corresponding to positions of irradiation of the focused ion beam on the sample image; a position of irradiation setting unit configured to set coordinates of the pixels included in the processing area image; a beam setting unit configured to set a dose amount of the focused ion beam irradiated from the focused ion beam irradiating mechanism according to intensities; and an interpolating unit configured to perform an interpolating process on the processing area image. | 06-24-2010 |
20100163756 | Single event upset (SEU) testing system and method - One embodiment of the invention relates to a circuit board for testing upsets caused by charged particles delivered under testing conditions. The circuit board comprises a device under test including an internal memory, a memory control unit to generate test patterns for comparison with data read from stored areas within the internal memory of the device under test, and a memory that is configured to only store error data. Other embodiments are described and claimed. | 07-01-2010 |
20100171048 | ION IMPLANTING APPARATUS - In an ion implanting apparatus | 07-08-2010 |
20100181500 | METHOD AND SYSTEM FOR LOW TEMPERATURE ION IMPLANTATION - A method comprises pre-cooling a first semiconductor wafer outside of a process chamber, from a temperature at or above 15° C. to a temperature below 5° C. The pre-cooled first wafer is placed inside the process chamber after performing the pre-cooling step. A low-temperature ion implantation is performed on the first wafer after placing the first wafer. | 07-22-2010 |
20100181501 | APPARATUS FOR SUB-ZERO DEGREE C ION IMPLANTATION - An ion implanter that comprises a chuck assembly having a chuck to clamp, hold, and cool a wafer is disclosed. The chuck is cooled by a cooling assembly circulated with a special coolant, such that the chuck can be maintained at very low temperatures. A mechanical design is provided to minimize the direct surface-to-surface contact area between the chuck and a base, which is employed to support the chuck. The mechanical design includes fasteners for providing mechanical support between the chuck and the base and thermal insulators for providing thermal insulation between the chuck and the base. | 07-22-2010 |
20100187447 | NON-CONDENSING THERMOS CHUCK - The present invention is directed to an apparatus and method of forming a thermos layer surrounding a chuck for holding a wafer during ion implantation. The thermos layer is located below a clamping surface, and comprises a vacuum gap and an outer casing encapsulating the vacuum gap. The thermos layer provides a barrier blocking condensation to the outside of the chuck within a process chamber by substantially preventing heat transfer between the chuck when it is cooled and the warmer environment within the process chamber. | 07-29-2010 |
20100187448 | ARRANGMENT AND METHOD FOR PROCESSING A SUBSTRATE - An arrangement for processing a substrate has an ion source for production of ions for processing the substrate using at least one process gas, and a process gas supply device, which is coupled to the ion source, in order to supply the process gas into the ion source. The process gas supply device has a tube composed of electrically insulating material, as well as a process gas supply regulator, which is designed such that the process gas is supplied at a pressure which is lower than the ambient pressure in the tube. | 07-29-2010 |
20100200774 | MULTI-SEQUENCE FILM DEPOSITION AND GROWTH USING GAS CLUSTER ION BEAM PROCESSING - A method of forming a thin film on a substrate is described. The method comprises depositing a first material layer on a substrate using a first gas cluster ion beam (GCIB), the first material layer comprising a first atomic constituent, and growing a second material layer from at least a surface portion of the first material layer by introducing a second atomic constituent using a second GCIB, the second material layer comprising a reaction product of the first and second atomic constituents. | 08-12-2010 |
20100200775 | Real Time Monitoring Ion Beam - Deflections from a desired trajectory of an ion beam outputted from an analyzer magnet are corrected with real-time monitoring of the ion beam deflection. Conductive structures are located close to the boundary of the beam exit, where each conductive structure is electrically insulated from other conductive structures and the analyzer magnet. Then, during implantation of ions into a wafer, continuous measuring of any current appearing on each conductive structure occurs, such that any collision between the conductive structure(s) and the ion beam is real-time monitored. By properly adjusting the shape/location/number of the conductive structure(s), and by properly adjusting the relative geometric relation among the conductive structure(s) and the desired trajectory, both the deflected angle and the deflected direction can be real-time monitored. Hence, the on-going implantation process and the implanter can be adjusted/maintained. | 08-12-2010 |
20100230617 | CHARGED PARTICLE RADIATION THERAPY - Among other things, an accelerator is mounted on a gantry to enable the accelerator to move through a range of positions around a patient on a patient support. The accelerator is configured to produce a proton or ion beam having an energy level sufficient to reach any arbitrary target in the patient from positions within the range. The proton or ion beam passes essentially directly from the accelerator to the patient. In some examples, the synchrocyclotron has a superconducting electromagnetic structure that generates a field strength of at least 6 Tesla, produces a beam of particles having an energy level of at least 150 MeV, has a volume no larger than 4.5 cubic meters, and has a weight less than 30 Tons. | 09-16-2010 |
20100301236 | Shorten Temperature Recovery Time of Low Temperature Ion Implantation - The present invention discloses a low temperature ion implantation by performing a heating process after the end of an implanting process and before the wafer is moved into the external environment. This invention actively raises wafer temperature at a time no later than implementation of the vacuum venting process, such that the condensed moisture induced by the temperature difference between a vacuum environment inside ion implanter and an external environment outside ion implanter is effectively minimized. The wafer can be heated at a loadlock, a robot for transferring wafer and/or an implantation chamber. The wafer can be heated by a gas, a liquid, a light and/or a heater embedded in a holder for holding the wafer. | 12-02-2010 |
20100327189 | ION IMPLANTATION APPARATUS AND A METHOD FOR FLUID COOLING - A hydrogen ion implanter for the exfoliation of silicon from silicon wafers uses a large scan wheel carrying 50+ wafers around its periphery and rotating about an axis. In one embodiment, the axis of rotation of the wheel is fixed and the wheel is formed with tensioned spokes supporting a rim carrying the wafer supports. The spokes may be used for carrying cooling fluid to and from the wafer supports. Detachable connections in the cooling fluid conduits in the vacuum chamber may comprise tandem seals with an intermediate chamber between them which can be vented outside the vacuum chamber, or independently vacuum pumped. In one embodiment, a ribbon beam of hydrogen ions is directed down on a peripheral edge of the wheel. The ribbon beam extends over the full radial width of wafers on the wheel. | 12-30-2010 |
20100327190 | ION IMPLANTATION APPARATUS AND A METHOD - A hydrogen ion implanter for the exfoliation of silicon from silicon wafers uses a large scan wheel carrying 50+ wafers around its periphery and rotating about an axis. In one embodiment, the axis of rotation of the wheel is fixed and a ribbon beam of hydrogen ions is directed down on a peripheral edge of the wheel. The ribbon beam extends over the full radial width of wafers on the wheel. The beam is generated by an ion source providing an extracted ribbon beam having at least 100 mm major cross-sectional diameter. The ribbon beam may be passed through a 90° bending magnet which bends the beam in the plane of the ribbon. The magnet provides intensity correction across the ribbon to compensate for the dependency on the radial distance from the wheel axis of the speed at which parts of the wafers pass through the ribbon beam. | 12-30-2010 |
20100327191 | Ion Implanter, Internal Structure of Ion Implanter and Method of Forming A Coating Layer in the Ion Implanter - An ion implanter includes a process chamber and a coating layer. The process chamber receives a substrate and provides a space to perform an ion implantation process on the substrate. The coating layer is disposed on an inner wall of the process chamber to reduce contamination of the substrate and includes the same material as that of the substrate. | 12-30-2010 |
20110012033 | Adjustable Louvered Plasma Electron Flood Enclosure - An apparatus is provided for reducing particle contamination in an ion implantation system. The apparatus has an enclosure having an entrance, an exit, and at least one louvered side having a plurality of louvers defined therein. A beamline of the ion implantation system passes through the entrance and exit, wherein the plurality of louvers of the at least one louvered side are configured to mechanically filter an edge of an ion beam traveling along the beamline. The enclosure can have two louvered sides and a louvered top, wherein respective widths of the entrance and exit of the enclosure, when measured perpendicular to the beamline, are generally defined by a position of the two louvered sides with respect to one another. One or more of the louvered sides can be adjustably mounted, wherein the width of one or more of the entrance and exit of the enclosure is controllable. | 01-20-2011 |
20110012034 | MANUFACTURING METHOD OF SEMICONDUCTOR DEVICE, METHOD FOR CONTROLLING ION BEAM, AND ION IMPLANTATION APPARATUS - The ion implantation apparatus includes a source head, an extraction electrode having a slit trough which a part of an ion beam outputted from the source head passes, a magnet for curving a trajectory of the ion beam passed through the slit, a target to be irradiated with the ion beam outputted from the magnet, an electric current measuring device facing an ion exit port of the source head through the slit of the extraction electrode, and a control portion for controlling a position of the extraction electrode based on a measured result of the current measuring device in a state that production of a magnetic field from the magnet is stopped. | 01-20-2011 |
20110037000 | Method And Apparatus for Uniformly Implanting A Wafer With An Ion Beam - Initially, an ion beam is formed as an elongated shape incident on a wafer, where the shape has a length along a first axis longer than a diameter of the wafer, and a width along a second axis shorter than the diameter of the wafer. Then, a center of the wafer is moved along a scan path intersecting the ion beam at a movement velocity, and the wafer is rotated around at a rotation velocity simultaneously. During the simultaneous movement and rotation, the wafer is totally overlapped with the ion beam along the first axis when the wafer intersects with the ion beam, and the rotation velocity is at most a few times of the movement velocity. Both the movement velocity and the rotation velocity can be a constant or have a velocity profile relative to a position of the ion beam across the wafer. | 02-17-2011 |
20110073779 | ION IMPLANTATION APPARATUS - An ion implanter has an implant wheel with a plurality of wafer carriers distributed about a periphery of the wheel. Each wafer carrier has a heat sink for removing heat from a wafer on the carrier during the implant process by thermal contact between the wafer and the heat sink. A respective wafer lift structure on each carrier is moveable between first and second positions, with the wafer supported spaced away from the heat sink and in thermal contact with the heat sink respectively. The lift structure is operated to move between the first and second positions wheel the implant is rotating. This allows control of wafer temperature during the implant process by adjusting the thermal contact between wafers and heat sinks. | 03-31-2011 |
20110073780 | OPTICAL HEATER FOR CRYOGENIC ION IMPLANTER SURFACE REGENERATION - In an ion implanter, one or more optical heaters are disposed above a pair of support arms. The support arms have an engaged positioned which is disposed beneath a platen and a retractable position displaced vertically away from the platen and rotated away from the platen in a direction parallel to a planar surface thereof. When the support arms are in the retracted position, the one or more optical heaters is configured to provide optical energy incident on surfaces of the cooling pads disposed on the support arms for removal of unwanted materials thereon. In this manner, the optical heaters are used during a regeneration cycle of cryogenic surfaces in an ion implanter. | 03-31-2011 |
20110073781 | ION IMPLANTATION APPARATUS - An ion implanter has an implant wheel with a plurality of wafer carriers distributed about a periphery of the wheel. Each wafer carrier has a heat sink for removing heat from a wafer on the carrier during the implant process by thermal contact between the wafer and the heat sink. The wafer carriers have wafer retaining fences formed as cylindrical rollers with axes in the respective wafer support planes of the wafer carriers. The cylindrical surfaces of the rollers provide wafer abutment surfaces which can move transversely to the wafer support surfaces so that no transverse loading is applied by the fences to wafer edges as the wafer is pushed against the heat sink by centrifugal force. The wafer support surfaces comprise layers of elastomeric material and the movable abutment surfaces of the fences allow even thermal coupling with the heat sink over the whole area of the wafer. | 03-31-2011 |
20110089342 | TECHNIQUES FOR PROCESSING A SUBSTRATE - Herein, an improved technique for processing a substrate is disclosed. In one particular exemplary embodiment, the technique may be achieved using a mask for processing the substrate. The mask may be incorporated into a substrate processing system such as, for example, an ion implantation system. The mask may comprise a first base; and a plurality of fingers spaced apart from one another to define one or more gaps. | 04-21-2011 |
20110089343 | TECHNIQUES FOR PROCESSING A SUBSTRATE - Herein, an improved technique for processing a substrate is disclosed. In one particular exemplary embodiment, the technique may be realized as a method for processing a substrate. The method may comprise directing an ion beam comprising a plurality of ions along an ion beam path, from an ion source to the substrate; disposing at least a portion of a mask in the ion beam path, between the ion source and the substrate; and translating one of the substrate and the mask relative to other one of the substrate and the mask. | 04-21-2011 |
20110101249 | SUBSTRATE HOLDER AND CLIPPING DEVICE - The invention relates to a substrate holder comprising a substrate support, moveable clipping device configured to engage a substrate positioned on the support in a first position and to be positioned away from the substrate in a different position, a positioning device for moving the clipping device from the second position towards the first position. To prevent a contact between the clipping device and support when no substrate is positioned thereon, an elastic stop element is used which limits the movement of the clipping device. The invention furthermore relates to a clipping device and an ion implanter using the substrate holder and the clipping device. | 05-05-2011 |
20110108742 | SYSTEM AND METHOD FOR HANDLING MULTIPLE WORKPIECES FOR MATRIX CONFIGURATION PROCESSING - A system for loading workpieces into a process chamber for processing in a matrix configuration includes a conveyor configured to transport multiple workpieces in a linear fashion. A workpiece hotel is configured to receive the multiple workpieces from the conveyor. The workpiece hotel comprises a matrix of cells arranged in N columns and M floors. A pick blade is configured to insert into the hotel and retract from the hotel in order to unload a plurality of substrates from a first floor into a single row of the pick blade, and to repeat the unloading operation to form a matrix comprising a plurality of rows of substrates disposed on the pick blade. In one example, the workpiece hotel has a staggered configuration that provides individual accessibility of each hotel cell. | 05-12-2011 |
20110121207 | Ion Beam Processing Apparatus - An ion-cut machine and method for slicing silicon ingots into thin wafers for solar cell manufacturing is set forth, amongst other embodiments and applications. One embodiment comprises two carousels: first carousel ( | 05-26-2011 |
20110140006 | METHOD AND APPARATUS FOR SPECIMEN FABRICATION - A focused ion beam apparatus, including: a specimen transferring unit having a probe to which a micro-specimen extracted from a specimen, can be joined through a joining deposition film, for transferring the micro-specimen to a sample holder; and wherein, the specimen transferring unit holds the probe which is joined through the joining deposition film to the micro-specimen extracted from the specimen, and the sample stage moves so that the sample holder mounted on the holder clasp is provided into an irradiated range of the focused ion beam, and the specimen transferring unit approaches the probe to the sample holder, and the gas nozzle supplies the deposition gas so that the micro-specimen is fixed to the sample holder through a fixing deposition film, and the ion beam irradiating optical system irradiates the focused ion beam to the micro-specimen fixed to the sample holder for various procedures. | 06-16-2011 |
20110155929 | APPARATUS AND SYSTEM FOR CONTROLLING ION RIBBON BEAM UNIFORMITY IN AN ION IMPLANTER - An ion beam blocking array configured to provide a mechanical means for adjusting the beam current profile of an ion ribbon beam by blocking the beam current at one or more locations across the ribbon beam. The ion beam blocking array includes a drive motor, an axle connected to the drive motor and a plurality of profile wheels disposed along the axle where each of the profile wheels is configured to rotate when the axle rotates. Each of the profile wheels is disposed across a width of the ribbon beam and has a position corresponding to a location along the width of the beam. | 06-30-2011 |
20110192993 | ADJUSTABLE SHADOW MASK ASSEMBLY FOR USE IN SOLAR CELL FABRICATIONS - An adjustable shadow mask implantation system comprising: an ion source configured to provide ions; and an shadow mask assembly configured to selectively allow ions from the ion source to pass therethrough to a substrate where they are implanted, wherein the shadow mask assembly is configured to adjust between a first position and a second position, wherein the shadow mask assembly enables ion implantation of multiple substantially parallel lines absent any lines with an intersecting orientation with respect to the multiple substantially parallel lines when set in the first position, and wherein the shadow mask assembly enables ion implantation of multiple substantially parallel lines and a line with an intersecting orientation with respect to the multiple substantially parallel lines when set in the second position. | 08-11-2011 |
20110198514 | USE OF PATTERN RECOGNITION TO ALIGN PATTERNS IN A DOWNSTREAM PROCESS - An improved, lower cost method of processing substrates, such as to create solar cells is disclosed. The doped regions are created on the substrate, using a mask or without the use of lithography or masks. After the implantation is complete, visual recognition is used to determine the exact region that was implanted. This information can then be used by subsequent process steps to maintain this alignment. This information can also be fed back to the ion implantation equipment to modify the implant parameters. These techniques can also be used in other ion implanter applications. | 08-18-2011 |
20110215262 | Method for Improving Implant Uniformity During Photoresist Outgassing - A method and apparatus is provided for improving implant uniformity of an ion beam experiencing pressure increase along the beam line. The method comprises generating a main scan waveform that moves an ion beam at a substantially constant velocity across a workpiece. A compensation waveform (e.g., quadratic waveform), having a fixed height and waveform, is also generated and mixed with the main scan waveform (e.g., through a variable mixer) to form a beam scanning waveform. The mixture ratio may be adjusted by an instantaneous vacuum pressure signal, which can be performed at much higher speed and ease than continuously modifying scan waveform. The mixture provides a beam scanning waveform comprising a non-constant slope that changes an ion beam's velocity as it moves across a workpiece. Therefore, the resultant beam scanning waveform, with a non-constant slope, is able to account for pressure non-uniformities in dose along the fast scan direction. | 09-08-2011 |
20110215263 | ION IMPLANTATION METHOD AND ION IMPLANTATION APPARATUS - An ion implantation method and the like by which a circular implantation region and a peripheral implantation region surrounding it and the dose amount of which is different from that of the circular implantation region can be formed within the surface of the substrate without the use of the step rotation of the substrate. The ion implantation method is forms a circular implantation region and a peripheral implantation region surrounding it and a dose amount of which is different from that of the circular implantation region within a surface of the substrate by making variable a scanning speed of the ion beam | 09-08-2011 |
20110226969 | ION IMPLANTATION DEVICE AND A METHOD OF SEMICONDUCTOR MANUFACTURING BY THE IMPLANTATION OF BORON HYDRIDE CLUSTER IONS - An ion implantation device and a method of manufacturing a semiconductor device is described, wherein ionized boron hydride molecular clusters are implanted to form P-type transistor structures. For example, in the fabrication of Complementary Metal-Oxide Semiconductor (CMOS) devices, the clusters are implanted to provide P-type doping for Source and Drain structures and for Polygates; these doping steps are critical to the formation of PMOS transistors. The molecular cluster ions have the chemical form B | 09-22-2011 |
20110233431 | IMPLANT METHOD AND IMPLANTER BY USING A VARIABLE APERTURE - A variable aperture within an aperture device is used to shape the ion beam before the substrate is implanted by shaped ion beam, especially to finally shape the ion beam in a position right in front of the substrate. Hence, different portions of a substrate, or different substrates, can be implanted respectively by different shaped ion beams without going through using multiple fixed apertures or retuning the ion beam each time. In other words, different implantations may be achieved respectively by customized ion beams without high cost (use multiple fixed aperture devices) and complex operation (retuning the ion beam each time). Moreover, the beam tune process for acquiring a specific ion beam to be implanted may be accelerated, to be faster than using multiple fixed aperture(s) and/or retuning the ion beam each time, because the adjustment of the variable aperture may be achieved simply by mechanical operation. | 09-29-2011 |
20110240889 | In-Vacuum Beam Defining Aperture Cleaning for Particle Reduction - A method is provided for reducing particle contamination in an ion implantation system, wherein an ion implantation system having source, mass analyzer, resolving aperture, decel suppression plate, and end station is provided. An ion beam is formed via the ion source, and a workpiece is transferred between an external environment and the end station for ion implantation thereto. A decel suppression voltage applied to the decel suppression plate is modulated concurrent with the workpiece transfer, therein causing the ion beam to expand and contract, wherein one or more surfaces of the resolving aperture and/or one or more components downstream of the resolving aperture are impacted by the ion beam, therein mitigating subsequent contamination of workpieces from previously deposited material residing on the one or more surfaces. The contamination can be mitigated by removing the previously deposited material or strongly adhering the previously deposited material to the one or more surfaces. | 10-06-2011 |
20110248190 | WAFER HANDLING METHOD AND ION IMPLANTER - An ion implanter performs ion implantation by irradiating a wafer having a notch at its outer peripheral region by an ion beam. In ion implanter, a twist angle adjustment mechanism is configured to adjust a twist angle, an aligner is configured to adjust an alignment angle, a wafer transfer device is configured to transfer the wafer between the aligner and the twist angle adjustment mechanism, an image processing device is configured to detect the twist angle of the wafer on the twist angle adjustment mechanism, and a control device is configured to carry out a twist control in which the wafer is rotated by the twist angle adjustment mechanism by an angle obtained from a first difference between the detected twist angle and the alignment angle and a second difference between the alignment angle and a target twist angle given as one of ion implantation conditions. | 10-13-2011 |
20110266466 | METHOD FOR MODIFYING A MATERIAL LAYER USING GAS CLUSTER ION BEAM PROCESSING - A method of modifying a material layer on a substrate is described. The method comprises forming the material layer on the substrate. Thereafter, the method comprises establishing a gas cluster ion beam (GCIB) having an energy per atom ratio ranging from about 0.25 eV per atom to about 100 eV per atom, and modifying the material layer by exposing the material layer to the GCIB. | 11-03-2011 |
20110272602 | Masked Ion Implant with Fast-Slow Scan - An improved method of producing solar cells utilizes a mask which is fixed relative to an ion beam in an ion implanter. The ion beam is directed through a plurality of apertures in the mask toward a substrate. The substrate is moved at different speeds such that the substrate is exposed to an ion dose rate when the substrate is moved at a first scan rate and to a second ion dose rate when the substrate is moved at a second scan rate. By modifying the scan rate, various dose rates may be implanted on the substrate at corresponding substrate locations. This allows ion implantation to be used to provide precise doping profiles advantageous for manufacturing solar cells. | 11-10-2011 |
20110278478 | METHOD AND IMPLANTER FOR IMPLANTING A WORKPIECE - To form one or more dose region(s) on a workpiece, a projected area of an ion beam on the workpiece is initially moved parallel to a long axis of the projected area from an edge of the workpiece to an opposite edge of the workpiece, and then is moved parallel to a short axis of the projected area a shifted distance shorter than the short axis of the projected area. Thereafter, repeat the moving step and the shifting step in sequence until all dose region(s) is completely formed. Accordingly, the cross-sectional size of the projected area is only proportional to the short axis when it is moved along its long axis. Hence, it is similar to use a narrow pen to paint a wall, and then it is suitable for forming different dose regions with different doses on a workpiece, such as the dose split. | 11-17-2011 |
20110291030 | ACTIVE DEW POINT SENSING AND LOAD LOCK VENTING TO PREVENT CONDENSATION ON WORKPIECES - A system, apparatus, and method is provided for preventing condensation on a workpiece in an end station of an ion implantation system. A workpiece is cooled in a first environment, and is transferred to a load lock chamber that is in selective fluid communication with the end station and a second environment, respectively. A workpiece temperature monitoring device is configured to measure a temperature of the workpiece in the load lock chamber. An external monitoring device measures a temperature and relative humidity in the second environment, and a controller is configured to determine a temperature of the workpiece at which condensation will not form on the workpiece when the workpiece is transferred from the load lock chamber to the second environment. | 12-01-2011 |
20110315899 | HANDLING BEAM GLITCHES DURING ION IMPLANTATION OF WORKPIECES - Glitches during ion implantation of a workpiece, such as a solar cell, can be compensated for. In one instance, a workpiece is implanted during a first pass at a first speed. This first pass results in a region of uneven dose in the workpiece. The workpiece is then implanted during a second pass at a second speed. This second speed is different from the first speed. The second speed may correspond to the entire workpiece or just the region of uneven dose in the workpiece. | 12-29-2011 |
20110315900 | METHOD FOR MANUFACTURING SOI SUBSTRATE - An object is to provide a method for manufacturing an SOI substrate, by which defective bonding can be prevented. An embrittled layer is formed in a region of a semiconductor substrate at a predetermined depth; an insulating layer is formed over the semiconductor substrate; the outer edge of the semiconductor substrate is selectively etched on the insulating layer side to a region at a greater depth than the embrittled layer; and the semiconductor substrate and a substrate having an insulating surface are superposed on each other and bonded to each other with the insulating layer interposed therebetween. The semiconductor substrate is heated to be separated at the embrittled layer while a semiconductor layer is left remaining over the substrate having an insulating surface. | 12-29-2011 |
20120025107 | Versatile Beam Glitch Detection System - A glitch duration threshold is determined based on an allowable dose uniformity, a number of passes of a workpiece through an ion beam, a translation velocity, and a beam size. A beam dropout checking routine repeatedly measures beam current during implantation. A beam dropout counter is reset each time beam current is sufficient. On a first observation of beam dropout, a counter is incremented and a position of the workpiece is recorded. On each succeeding measurement, the counter is incremented if beam dropout continues, or reset if beam is sufficient. Thus, the counter indicates a length of each dropout in a unit associated with the measurement interval. The implant routine stops only when the counter exceeds the glitch duration threshold and a repair routine is performed, comprising recalculating the glitch duration threshold based on one fewer translations of the workpiece through the beam, and performing the implant routine starting at the stored position. | 02-02-2012 |
20120056110 | USING BEAM BLOCKERS TO PERFORM A PATTERNED IMPLANT OF A WORKPIECE - Blockers in an ion beam blocker unit selectively block or trim an ion beam. In one instance, the ion beam has first current regions and second current regions. These current regions may be unequal. The ion beam is then implanted into a workpiece to form regions with different doses. The workpiece may be scanned so that the entirety of its surface is implanted. | 03-08-2012 |
20120085941 | ION IMPLANTATION APPARATUS AND METHOD - According to one embodiment, a material gas led into a vacuum container is ionized. When ions are implanted into a semiconductor substrate, gas is exhausted from the vacuum container by a pump and the gas exhausted by the pump is returned to the vacuum container and reused. This makes it possible efficiently use the material gas. | 04-12-2012 |
20120104285 | ION IMPLANTATION METHOD AND ION IMPLANTATION APPARATUS - An ion implantation method and the like by which a circular implantation region and a peripheral implantation region surrounding it and the dose amount of which is different from that of the circular implantation region can be formed within the surface of the substrate without the use of the step rotation of the substrate. The ion implantation method forms a circular implantation region and a peripheral implantation region surrounding it and a dose amount of which is different from that of the circular implantation region within a surface of the substrate by making variable a scanning speed of the ion beam | 05-03-2012 |
20120126147 | SEMICONDUCTOR STRUCTURE MADE USING IMPROVED PSEUDO-SIMULTANEOUS MULTIPLE ION IMPLANTATION PROCESS - Methods and apparatus provide for: a source simultaneously producing first plasma, which includes a first species of ions, and second plasma, which includes a second, differing, species of ions; an accelerator system including an analyzer magnet, which cooperate to simultaneously: (i) accelerate the first and second plasma along an initial axis, (ii) alter a trajectory of the first species of ions from the first plasma, thereby producing at least one first ion beam along a first axis, which is transverse to the initial axis, and (iii) alter a trajectory of the second species of ions from the second plasma, thereby producing at least one second ion beam along a second axis, which is transverse to the initial axis and the first axis; and a beam processing system operating to simultaneously direct the first and second ion beams toward a semiconductor wafer such that the first and second species of ions bombard an implantation surface of the semiconductor wafer to create an exfoliation layer therein. | 05-24-2012 |
20120241648 | HEAT LIP SEAL FOR CRYOGENIC PROCESSING - In an ion implanter, an elastomer seal is used for cryogenic processing and includes an internal cavity defined by a pair of opposing side walls and a bottom wall disposed therebetween. An electrically conductive spring is disposed within the cavity and extends along a length of the seal. The seal is configured to provide a lateral biasing force against the pair of opposing side walls and to conduct an applied current which results in heat being generated that emanates at least along the pair of opposing side walls. In this manner, the heat from the spring maintains the temperature of the seal above its brittle point. This allows the elastomer seal to maintain its pliability and consequently its sealing integrity during processing at cryogenic temperatures. | 09-27-2012 |
20130009075 | BEAM LINE SYSTEM OF ION IMPLANTER - A beam line system includes a hollow tube and a plurality of protruding structures. The hollow tube has an inlet and an outlet. An ion beam emitted by the ion implanter is introduced into the hollow tube through the inlet and exited from the hollow tube through the outlet. The protruding structures are formed on an inner wall of the hollow tube. Each of the protruding structures has a reflective surface for reflecting a portion of the ion beam. | 01-10-2013 |
20130056655 | ION IMPLANT APPARATUS AND METHOD OF ION IMPLANTATION - An apparatus and a method of ion implantation using a rotary scan assembly having an axis of rotation and a periphery. A plurality of substrate holders is distributed about the periphery, and the substrate holders are arranged to hold respective planar substrates. Each planar substrate has a respective geometric center on the periphery. A beam line assembly provides a beam of ions for implantation in the planar substrates on the holders. The beam line assembly is arranged to direct said beam along a final beam path. | 03-07-2013 |
20130248738 | PLATEN CLAMPING SURFACE MONITORING - An ion implanter includes a platen having a clamping surface configured to support a wafer for treatment with ions, the platen also having at least one pair of electrodes under the clamping surface, a clamping power supply configured to provide an AC signal to the at least one pair of electrodes and a sensed signal representative of the AC signal, and a controller. The controller is configured to receive the sensed signal from the clamping power supply when no wafer is clamped to the clamping surface. The controller is further configured to monitor the sensed signal and determine if the sensed signal is representative of deposits on the clamping surface exceeding a predetermined deposit threshold. | 09-26-2013 |
20130256566 | ION IMPLANTATION APPARATUS AND CONTROL METHOD THEREOF - A vertical profile, a horizontal profile, and an integrated current value of an ion beam are measured by a plurality of stationary beam measuring instruments and a movable or stationary beam measuring device. At a beam current adjustment stage before ion implantation, a control device simultaneously performs at least one of adjustment of a beam current to a preset value of the beam current, adjustment of a horizontal beam size that is necessary to secure uniformity of the horizontal ion beam density, and adjustment of a vertical beam size that is necessary to secure the uniformity of the vertical ion implantation distribution on the basis of a measurement value of the stationary beam measuring instruments and the movable or stationary beam measuring device. | 10-03-2013 |
20130264498 | SYSTEM AND METHOD OF ION NEUTRALIZATION WITH MULTIPLE-ZONED PLASMA FLOOD GUN - An apparatus comprises a plasma flood gun for neutralizing a positive charge buildup on a semiconductor wafer during a process of ion implantation using an ion beam. The plasma flood gun comprises more than two arc chambers, wherein each arc chamber is configured to generate and release electrons into the ion beam in a respective zone adjacent to the semiconductor wafer. | 10-10-2013 |
20140291554 | Source Bushing Shielding - The source bushing assembly has a source bushing having an internal vacuum side and an external atmosphere side, a first shield of annular shape disposed at one end of the source bushing in spaced concentric relation to reduce formation of an electrically conductive coating on the source bushing, a second shield of annular shape disposed at an opposite end of the source bushing in spaced concentric relation to prevent arcing on the source bushing and an internally disposed concentric X-ray shield. | 10-02-2014 |
20140306127 | METHOD AND SYSTEM FOR MODIFYING SUBSTRATE RELIEF FEATURES USING ION IMPLANTATION - A method of treating resist features comprises positioning, in a process chamber, a substrate having a set of patterned resist features on a first side of the substrate and generating a plasma in the process chamber having a plasma sheath adjacent to the first side of the substrate. The method may further comprise modifying a shape of a boundary between the plasma and the plasma sheath with a plasma sheath modifier so that a portion of the shape of the boundary is not parallel to a plane defined by a front surface of the substrate facing the plasma, wherein ions from the plasma impinge on the patterned resist features over a wide angular range during a first exposure. | 10-16-2014 |
20140326901 | EXTRACTION ELECTRODE ASSEMBLY VOLTAGE MODULATION IN AN ION IMPLANTATION SYSTEM - A method is disclosed for reducing particle contamination in an ion implantation system, wherein an ion beam is created via the ion source operating in conjunction with an extraction electrode assembly. A cathode voltage is applied to the ion source for generating ions therein, and a suppression voltage is applied to the extraction assembly for preventing electrons in the ion beam from being drawn into the ion source. The suppression voltage is selectively modulated, thereby inducing a current flow or an arc discharge through the extraction assembly to remove deposits on surfaces thereof to mitigate subsequent contamination of workpieces. An improvement to an ion implantation system is also disclosed in accordance with the foregoing, wherein a controller is configured to selectively modulate a voltage between a predetermined voltage and a predetermined suppression voltage generally concurrent with the transferring of the workpiece, thereby inducing a current flow or an arc discharge through the extraction electrode assembly to remove deposits on surfaces thereof to mitigate subsequent contamination of workpieces. | 11-06-2014 |
20140353526 | METHOD AND SYSTEM FOR FORMING HIGH ACCURACY PATTERNS USING CHARGED PARTICLE BEAM LITHOGRAPHY - A method and system for fracturing or mask data preparation for charged particle beam lithography are disclosed in which a plurality of charged particle beam shots is determined that will form a pattern on a surface using a multi-beam charged particle beam writer, where the sensitivity of the pattern on the surface to manufacturing variation is reduced by increasing edge slope. | 12-04-2014 |
20140361197 | WORKPIECE CARRIER - A workpiece carrier comprises a first plate having a first outer diameter, a first inner diameter, and a first recess extending a first distance from the first inner diameter toward the first outer diameter. The workpiece carrier further comprises a second plate having a second outer diameter, a second inner diameter, and a second recess extending a second distance from the second inner diameter toward the second outer diameter. A plurality of mating features associated with the first plate and second plate are configured to selectively fix a position of a first workpiece between the first plate and second plate within the first recess and second recess. | 12-11-2014 |
20150076371 | LITHO CLUSTER AND MODULIZATION TO ENHANCE PRODUCTIVITY - The present disclosure relates to a lithographic tool arrangement for semiconductor workpiece processing. The lithographic tool arrangement groups lithographic tools into clusters, and selectively transfers a semiconductor workpiece between a plurality of lithographic tools of a first type in a first cluster to a plurality of lithographic tools of a second type in a second cluster. The selective transfer is achieved though a transfer assembly, which is coupled to a defect scan tool that identifies defects generated in the lithographic tool of the first type. The disclosed lithographic tool arrangement also utilizes shared structural elements such as a housing assembly, and shared functional elements such as gases and chemicals. The lithographic tool arrangement may consist of baking, coating, exposure, and development units configured to provide a modularization of these various components in order to optimize throughput and efficiency for a given lithographic fabrication process. | 03-19-2015 |
20150102237 | Techniques For Processing A Substrate - Herein, an improved technique for processing a substrate is disclosed. In one particular exemplary embodiment, the technique may be achieved using a mask for processing the substrate. The mask may be incorporated into a substrate processing system such as, for example, an ion implantation system. The mask may comprise one or more first apertures disposed in a first row; and one or more second apertures disposed in a second row, each row extending along a width direction of the mask, wherein the one or more first apertures and the one or more second apertures are non-uniform. | 04-16-2015 |
20150303027 | Charged-Particle Beam Lithographic System - A charged-particle beam lithographic system ( | 10-22-2015 |
20150318140 | Multi-Source Plasma Focused Ion Beam System - The present invention provides a plasma ion beam system that includes multiple gas sources and that can be used for performing multiple operations using different ion species to create or alter submicron features of a work piece. The system preferably uses an inductively coupled, magnetically enhanced ion beam source, suitable in conjunction with probe-forming optics sources to produce ion beams of a wide variety of ions without substantial kinetic energy oscillations induced by the source, thereby permitting formation of a high resolution beam. | 11-05-2015 |
20150340202 | ION IMPLANTATION APPARATUS - An ion implantation apparatus includes a scanning unit, the scanning unit including a scanning electrode device that allows a deflecting electric field to act on an ion beam incident along a reference trajectory and scans the ion beam in a horizontal direction, and an upstream electrode device provided upstream of the scanning electrode device. The scanning electrode device includes a pair of scanning electrodes provided to face each other in the horizontal direction with the reference trajectory interposed therebetween and a pair of beam transport correction electrodes provided to face each other in a vertical direction perpendicular to the horizontal direction with the reference trajectory interposed therebetween. Each of the pair of beam transport correction electrode includes a beam transport correction inlet electrode body protruding toward the reference trajectory in the vertical direction in the vicinity of an inlet of the scanning electrode device. | 11-26-2015 |
20150364297 | BEAM IRRADIATION APPARATUS AND BEAM IRRADIATION METHOD - Provided is a beam irradiation apparatus including: a beam scanner that is configured such that a charged particle beam is reciprocatively scanned in a scanning direction; a measurement device that is capable of measuring an angular component of charged particles incident into a region of a measurement target; and a data processor that calculates effective irradiation emittance of the charged particle beam using results measured by the measurement device. The measurement device measures a time dependent value for angular distribution of the charged particle beam. The data processor transforms time information included in the time dependent value for the angular distribution to position information and thus calculates the effective irradiation emittance. The effective irradiation emittance represents emittance of a virtual beam bundle, the virtual beam bundle being formed by summing portions of the charged particle beam which are incident into the region of the measurement target. | 12-17-2015 |
20160071695 | AN ION IMPLANTATION MACHINE PRESENTING INCREASED PRODUCTIVITY - The present invention relates to an ion implantation machine | 03-10-2016 |
20160133439 | HIGH ENERGY ION IMPLANTER, BEAM CURRENT ADJUSTER, AND BEAM CURRENT ADJUSTMENT METHOD - A beam current adjuster for an ion implanter includes a variable aperture device which is disposed at an ion beam focus point or a vicinity thereof. The variable aperture device is configured to adjust an ion beam width in a direction perpendicular to an ion beam focusing direction at the focus point in order to control an implanting beam current. The variable aperture device may be disposed immediately downstream of a mass analysis slit. The beam current adjuster may be provided with a high energy ion implanter including a high energy multistage linear acceleration unit. | 05-12-2016 |
20160163510 | Boron Implanting Using A Co-Gas - An apparatus and methods of improving the ion beam quality of a halogen-based source gas are disclosed. Unexpectedly, the introduction of a noble gas, such as argon, to an ion source chamber may increase the percentage of desirable ion species, while decreasing the amount of contaminants and halogen-containing ions. This is especially beneficial in non-mass analyzed implanters, where all ions are implanted into the workpiece. In one embodiment, a first source gas, comprising a dopant and a halogen is introduced into an ion source chamber, a second source gas comprising a hydride, and a third source gas comprising a noble gas are also introduced. The combination of these three source gases produces an ion beam having a higher percentage of pure dopant ions than would occur if the third source gas were not used. | 06-09-2016 |
20160189926 | Beam Profiling Speed Enhancement for Scanned Beam Implanters - An ion implantation system and method are provided where an ion beam is tuned to a first process recipe. The ion beam is scanned along a scan plane at a first frequency, defining a first scanned ion beam. A beam profiling apparatus is translated through the first scanned ion beam and one or more properties of the first scanned ion beam are measured across a width of the first scanned ion, thus defining a first beam profile associated with the first scanned ion beam. The ion beam is then scanned at a second frequency, thus defining a second scanned ion beam, wherein the second frequency is less than the first frequency. A second beam profile associated with the second scanned ion beam is determined based, at least in part, on the first beam profile. Ions are subsequently implanted into a workpiece via the second scanned ion beam. | 06-30-2016 |
20160189927 | Method of Measuring Vertical Beam Profile in an Ion Implantation System Having a Vertical Beam Angle Device - An ion implantation system measurement system has a scan arm that rotates about an axis and a workpiece support to translate a workpiece through the ion beam. A first measurement component downstream of the scan arm provides a first signal from the ion beam. A second measurement component with a mask is coupled to the scan arm to provide a second signal from the ion beam with the rotation of the scan arm. The mask permits varying amounts of the ion radiation from the ion beam to enter a Faraday cup based on an angular orientation between the mask and the ion beam. A blocking plate selectively blocks the ion beam to the first faraday based on the rotation of the scan arm. A controller determines an angle and vertical size of the ion beam based on the first signal, second signal, and orientation between the mask and ion beam as the second measurement component rotates. | 06-30-2016 |
20160189928 | SYSTEM AND METHOD TO IMPROVE PRODUCTIVITY OF HYBRID SCAN ION BEAM IMPLANTERS - A method for improving the productivity of a hybrid scan implanter by determining an optimum scan width is provided. A method of tuning a scanned ion beam is provided, where a desired beam current is determined to implant a workpiece with desired properties. The scanned beam is tuned utilizing a setup Faraday cup. A scan width is adjusted to obtain an optimal scan width using setup Faraday time signals. Optics are tuned for a desired flux value corresponding to a desired dosage. Uniformity of a flux distribution is controlled when the desired flux value is obtained. An angular distribution of the ion beam is further measured. | 06-30-2016 |
20160189929 | RAPID TEM SAMPLE PREPARATION METHOD WITH BACKSIDE FIB MILLING - A method for TEM sample preparation with backside milling of a sample extracted from a workpiece in an energetic-beam instrument such as a FIB-SEM is disclosed. The method includes rotating a nanomanipulator probe tip holding an extracted sample by an angle calculated according to the geometry of the apparatus; moving the instrument stage to position a TEM grid in a fixed holder so that the plane of the TEM grid is substantially parallel to the required plane for the TEM sample; attaching the extracted sample to the TEM grid; and, tilting the stage by a stage-tilt angle, while maintaining the holder in the fixed orientation with respect to the stage, so that the axis of the ion beam is made substantially parallel to the required plane for the TEM sample; thereby placing the extracted sample into position for allowing backside milling to prepare a thinned cross-sectional sample for TEM viewing. | 06-30-2016 |
20160254122 | METHOD FOR GENERATING PARAMETER PATTERN, ION IMPLANTATION METHOD AND FEED FORWARD SEMICONDUCTOR MANUFACTURING METHOD | 09-01-2016 |
20170236686 | ION BEAM IRRADIATION APPARATUS | 08-17-2017 |