ADVANCED ION BEAM TECHNOLOGY, INC. Patent applications |
Patent application number | Title | Published |
20150255242 | PLASMA-BASED MATERIAL MODIFICATION USING A PLASMA SOURCE WITH MAGNETIC CONFINEMENT - A plasma-based material modification system for material modification of a work piece may include a plasma source chamber coupled to a process chamber. A support structure, configured to support the work piece, may be disposed within the process chamber. The plasma source chamber may include a first plurality of magnets, a second plurality of magnets, and a third plurality of magnets that surround a plasma generation region within the plasma source chamber. The plasma source chamber may be configured to generate a plasma having ions within the plasma generation region. The third plurality of magnets may be configured to confine a majority of electrons of the plasma having energy greater than 10 eV within the plasma generation region while allowing ions from the plasma to pass through the third plurality of magnets into the process chamber for material modification of the work piece. | 09-10-2015 |
20150056380 | ION SOURCE OF AN ION IMPLANTER - An ion source uses at least one induction coil to generate ac magnetic field to couple rf/VHF power into a plasma within a vessel, where the excitation coil may be a single set of turns each turn having lobes or multiple separate sets of windings. The excitation coil is positioned outside and proximate that side of the vessel that is opposite to the extraction slit, and elongated parallel to the length dimension of the extraction slit. The conducting shield(s) positioned outside or integrated with the well of the vessel are used to block the capacitive coupling to the plasma and/or to collect any rf/VHF current may be coupled into the plasma. The conducting shield positioned between the vessel and the coil set can either shield the plasma from capacitive coupling from the excitation coils, or be tuned to have a higher rf/VHF voltage to ignite or clean the source. | 02-26-2015 |
20150031181 | REPLACEMENT SOURCE/DRAIN FINFET FABRICATION - A finFET is formed having a fin with a source region, a drain region, and a channel region between the source and drain regions. The fin is etched on a semiconductor wafer. A gate stack is formed having an insulating layer in direct contact with the channel region and a conductive gate material in direct contact with the insulating layer. The source and drain regions are etched leaving the channel region of the fin. Epitaxial semiconductor is grown on the sides of the channel region that were adjacent the source and drain regions to form a source epitaxy region and a drain epitaxy region. The source and drain epitaxy regions are doped in-situ while growing the epitaxial semiconductor. | 01-29-2015 |
20140261181 | BEAM CONTROL ASSEMBLY FOR RIBBON BEAM OF IONS FOR ION IMPLANTATION - A beam control assembly to shape a ribbon beam of ions for ion implantation includes a first bar, second bar, first coil of windings of electrical wire, second coil of windings of electrical wire, first electrical power supply, and second electrical power supply. The first coil is disposed on the first bar. The first coil is the only coil disposed on the first bar. The second bar is disposed opposite the first bar with a gap defined between the first and second bars. The ribbon beam travels between the gap. The second coil is disposed on the second bar. The second coil is the only coil disposed on the second bar. The first electrical power supply is connected to the first coil without being electrically connected to any other coil. The second electrical power supply is connected to the second coil without being electrically connected to any other coil. | 09-18-2014 |
20140212595 | MAGNETIC FIELD FLUCTUATION FOR BEAM SMOOTHING - The time-averaged ion beam profile of an ion beam for implanting ions on a work piece may be smoothed to reduce noise, spikes, peaks, and the like and to improve dosage uniformity. Auxiliary magnetic field devices, such as electromagnets, may be located along an ion beam path and may be driven by periodic signals to generate a fluctuating magnetic field to smooth the ion beam profile (i.e., beam current density profile). The auxiliary magnetic field devices may be positioned outside the width and height of the ion beam, and may generate a non-uniform fluctuating magnetic field that may be strongest near the center of the ion beam where the highest concentration of ions may be positioned. The fluctuating magnetic field may cause the beam profile shape to change continuously, thereby averaging out noise over time. | 07-31-2014 |
20140175568 | REPLACEMENT SOURCE/DRAIN FINFET FABRICATION - A finFET is formed having a fin with a source region, a drain region, and a channel region between the source and drain regions. The fin is etched on a semiconductor wafer. A gate stack is formed having an insulating layer in direct contact with the channel region and a conductive gate material in direct contact with the insulating layer. The source and drain regions are etched leaving the channel region of the fin. Epitaxial semiconductor is grown on the sides of the channel region that were adjacent the source and drain regions to form a source epitaxy region and a drain epitaxy region. The source and drain epitaxy regions are doped in-situ while growing the epitaxial semiconductor. | 06-26-2014 |
20140161987 | 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. | 06-12-2014 |
20140151573 | MULTI-ENERGY ION IMPLANTATION - In a multi-energy ion implantation process, an ion implanting system having an ion source, an extraction assembly, and an electrode assembly is used to implant ions into a target. An ion beam having a first energy may be generated using the ion source and the extraction assembly. A first voltage may be applied across the electrode assembly. The ion beam may enter the electrode assembly at the first energy, exit the electrode assembly at a second energy, and implant ions into the target at the second energy. A second voltage may be applied across the electrode assembly. The ion beam may enter the electrode assembly at the first energy, exit the electrode assembly at a third energy, and implants ions into the target at the third energy. The third energy may be different from the second energy. | 06-05-2014 |
20140151572 | GAS MIXTURE METHOD AND APPARATUS FOR GENERATING ION BEAM - A gas mixture method and apparatus of prolonging lifetime of an ion source for generating an ion beam particularly an ion beam containing carbon is proposed here. By mixing the dopant gas and the minor gas together to generate an ion beam, undesired reaction between the gas species and the ion source can be mitigated and thus lifetime of the ion source can be prolonged. Accordingly, quality of ion beam can be maintained. | 06-05-2014 |
20140097487 | PLASMA DOPING A NON-PLANAR SEMICONDUCTOR DEVICE - In plasma doping a non-planar semiconductor device, a substrate having a non-planar semiconductor body formed thereon is obtained. The substrate having the non-planar semiconductor body may be placed into a chamber. A plasma may be formed in the chamber and the plasma may contain dopant ions. A first bias voltage may be generated to implant dopant ions into a region of the non-planar semiconductor body. A second bias voltage may be generated to implant dopant ions into the same region. In one example, the first bias voltage and the second bias voltage may be different. | 04-10-2014 |
20140054679 | DOPING A NON-PLANAR SEMICONDUCTOR DEVICE - In doping a non-planar semiconductor device, a substrate having a non-planar semiconductor body formed thereon is obtained. A first ion implant is performed in a region of the non-planar semiconductor body. The first ion implant has a first implant energy and a first implant angle. A second ion implant is performed in the same region of the non-planar semiconductor body. The second ion implant has a second implant energy and a second implant angle. The first implant energy may be different from the second implant energy. Additionally, the first implant angle may be different from the second implant angle. | 02-27-2014 |
20130239892 | BEAM CONTROL ASSEMBLY FOR RIBBON BEAM OF IONS FOR ION IMPLANTATION - A beam control assembly to shape a ribbon beam of ions for ion implantation includes a first bar, second bar, first coil of windings of electrical wire, second coil of windings of electrical wire, first electrical power supply, and second electrical power supply. The first coil is disposed on the first bar. The first coil is the only coil disposed on the first bar. The second bar is disposed opposite the first bar with a gap defined between the first and second bars. The ribbon beam travels between the gap. The second coil is disposed on the second bar. The second coil is the only coil disposed on the second bar. The first electrical power supply is connected to the first coil without being electrically connected to any other coil. The second electrical power supply is connected to the second coil without being electrically connected to any other coil. | 09-19-2013 |
20130187349 | SCAN HEAD AND SCAN ARM USING THE SAME - A scan head assembled to a scan arm for an ion implanter and a scan arm using the same are provided, wherein the scan head is capable of micro tilting a work piece and comprises a case, a shaft assembly, an electrostatic chuck, a first driving mechanism and a micro-tilt mechanism. The shaft assembly passes through a first side of the case and has a twist axis. The electrostatic chuck is fastened on a first end of the shaft assembly outside the case for holding the work piece. The first driving mechanism is disposed within the case and capable of driving the shaft assembly and the ESC to rotate about the twist axis. The micro-tilt mechanism is disposed within the case and capable of driving the shaft assembly and the ESC to tilt relative to the case. | 07-25-2013 |
20130187207 | REPLACEMENT SOURCE/DRAIN FINFET FABRICATION - A finFET is formed having a fin with a source region, a drain region, and a channel region between the source and drain regions. The fin is etched on a semiconductor wafer. A gate stack is formed having an insulating layer in direct contact with the channel region and a conductive gate material in direct contact with the insulating layer. The source and drain regions are etched to expose a first region of the fin. A portion of the first region is then doped with a dopant. | 07-25-2013 |
20130130484 | ION IMPLANTER AND ION IMPLANT METHOD THEREOF - An ion implanter and an ion implant method are disclosed. Essentially, the wafer is moved along one direction and an aperture mechanism having an aperture is moved along another direction, so that the projected area of an ion beam filtered by the aperture is two-dimensionally scanned over the wafer. Thus, the required hardware and/or operation to move the wafer may be simplified. Further, when a ribbon ion beam is provided, the shape/size of the aperture may be similar to the size/shape of a traditional spot beam, so that a traditional two-dimensional scan may be achieved. Optionally, the ion beam path may be fixed without scanning the ion beam when the ion beam is to be implanted into the wafer, also the area of the aperture may be adjustable during a period of moving the aperture across the ion beam. | 05-23-2013 |
20130057250 | APPARATUS AND METHOD FOR MEASURING ION BEAM CURRENT - Techniques for measuring ion beam current, especially for measuring low energy ion beam current, are disclosed. The technique may be realized as an ion beam current measurement apparatus having at least a planar Faraday cup and a voltage assembly. The planar Faraday cup is located close to an inner surface of a chamber wall, and intersects an ion beam path. The voltage assembly is located outside a chamber having the chamber wall. Therefore, by properly adjusting the electric voltage applied on the planar Faraday cup by the voltage assembly, some undesired charged particles may be adequately suppressed. Further, the planar Faraday cup may surround an opening of an additional Faraday cup being any conventional Faraday cup. Therefore, the whole ion beam may be received and measured well by the larger cross-section area of the planar Faraday cup on the ion beam path. | 03-07-2013 |
20130026722 | EXTREMELY LOW TEMPERATURE ROTARY UNION - A chuck assembly has a wafer chuck attached to a shaft that has a passage defined therewithin. The chuck assembly also has a seal module that has a rotatable assembly and a fixed assembly. The rotatable assembly is disposed around and anchored to the shaft and has a spacer, a rotatable collar, a rotatable diaphragm, and a rotatable seal ring connected to the rotatable collar through the diaphragm with a leak-tight seal. The fixed assembly is disposed around the spacer and has a fixed collar and a fixed seal ring that is sealed to the fixed collar with a leak-tight seal. The fixed collar has a passage defined therewithin that has an opening that connects through the spacer to the passage defined within the shaft. The chuck assembly further includes a housing, to which the fixed assembly is fastened, that may be affixed to a base. | 01-31-2013 |
20130026539 | REPLACEMENT SOURCE/DRAIN FINFET FABRICATION - A finFET is formed having a fin with a source region, a drain region, and a channel region between the source and drain regions. The fin is etched on a semiconductor wafer. A gate stack is formed having an insulating layer in direct contact with the channel region and a conductive gate material in direct contact with the insulating layer. The source and drain regions are etched leaving the channel region of the fin. Epitaxial semiconductor is grown on the sides of the channel region that were adjacent the source and drain regions to form a source epitaxy region and a drain epitaxy region. The source and drain epitaxy regions are doped in-situ while growing the epitaxial semiconductor. | 01-31-2013 |
20130001433 | Real Time Monitoring Ion Beam - The invention provides a method to real time monitor the ion beam. Initially, turn on an ion implanter which has a wafer holder, a Faraday cup and a measurement device positioned close to a special portion of a pre-determined ion beam path of the ion beam, wherein the Faraday cup is positioned downstream the wafer holder and the measurement device is positioned upstream the wafer holder. Then, measure a first ion beam current received by the Faraday cup and a second ion beam current received by the measurement device. By continuously measuring the first and second ion beam current, the ion beam is real-time monitored even the Faraday cup is at least partially blocked during the period of moving the wafer holder across the ion beam. Accordingly, the on-going implantation process and the operation of the implanter can be adjusted. | 01-03-2013 |
20120317993 | APPARATUS AND METHOD FOR CONTROLLING WORKPIECE TEMPERATURE - An atmospheric controlled chamber includes a support assembly capable of holding a workpiece over a specific surface of the support assembly, a heat-transfer assembly located close to the support assembly and capable of transferring heat to and from the exterior of the chamber, and at least one thermopile device disposed in the support assembly. The thermopile device(s) is configured to transfer heat between the specific surface (or viewed as the held workpiece) and the heat-transfer assembly. A gas assembly is optionally surrounded by the chamber wall and capable of ensuring the existence and controlling the pressure of an essentially static gas between the held workpiece and the specific surface, wherein the gas is used as a thermal medium for conducting heat. The thermopile device acts as an efficient heat pump, so as to provide extra lower/higher workpiece temperature, a greater cooling/heating rates, and more flexible rate control. | 12-20-2012 |
20120281333 | TEMPERATURE-CONTROLLABLE ELECTROSTATIC CHUCK - The invention is directed to a temperature-controllable electrostatic chuck having a heat-transfer body, one or more electrodes and one or more thermopile devices. The heat-transfer body transfers heat between the interior of the electrostatic chuck and the exterior of the electrostatic chuck via a heat-transfer assembly with heat-transfer fluid circulated to and from an external chiller. The one or more thermopile devices are in series between the heat-transfer body and a top surface of the electrostatic chuck, so that heat may be further transferred between a workpiece held on the top surface and the heat-transfer body. Accordingly, because the workpiece temperature may be adjusted by both the external chiller and the thermopile devices, the workpiece temperature may be further lowered when the cold sides of the thermopile device face the workpiece. Otherwise, the workpiece temperature may be further elevated when the hot sides of the thermopile device face the workpiece. | 11-08-2012 |
20120196047 | DETERMINING RELATIVE SCAN VELOCITY TO CONTROL ION IMPLANTATION OF WORK PIECE - To select a relative velocity profile to be used in scanning an actual work piece with an ion implant beam of an ion implantation tool, the implantation of a virtual work piece is simulated. A dose distribution is calculated across the virtual work piece based on an implant beam profile and a relative velocity profile. A new relative velocity profile is then determined based on the calculated dose distribution and the relative velocity profile used in calculating the dose distribution. A new dose distribution is then calculated using the new relative velocity profile. A new relative velocity profile is determined and a corresponding new dose distribution is calculated iteratively until the new dose distribution meets one or more predetermined criteria. The new relative velocity profile is stored as the selected relative velocity profile when the new dose distribution meets the one or more predetermined criteria. | 08-02-2012 |
20120187290 | APPARATUS FOR ADJUSTING ION BEAM BY BENDED BAR MAGNETS - Apparatus and method for adjusting an ion beam between a mass analyzer and a substrate holder. Herein, one or more bended, such as arch-shaped, curved or zigzag shaped, bar magnets are configured to apply one or more magnetic fields to adjust the shape or cross section of an ion beam passing through a space partially surrounded by the one or more bended bar magnets. At least one of the gap width between neighbor bended bar magnets, the curvature of each bended bar magnet and the current flowing through each bended bar magnet may be fixed or adjusted dependently or independently. Therefore, the Lorentz force applied on the ion beam along different directions may be changed in a desired manner, and then the ion beam may be flexibly elongated, compressed or shaped to meet the process requirement. | 07-26-2012 |
20120126137 | ION IMPLANTATION METHOD AND ION IMPLANTER - An ion implantation method and an ion implanter with a beam profiler are proposed in this invention. The method comprises setting scan conditions, detecting the ion beam profile, calculating the dose profile according to the detected ion beam profile and scan conditions, determining the displacement for ion implantation and implanting ions on a wafer surface. The ion implanter used the beam profiler to detect the ion beam profile, calculate dose profile and determine the displacement and used the displacement in ion implantation for optimizing, wherein the beam profiler comprises a body with ion channel and detection unit behind the ion channel in the body for beam profile detection. The beam profiler may be a 1-dimensional, 2-dimensional or angle beam profiler. | 05-24-2012 |
20120115318 | METHOD FOR LOW TEMPERATURE ION IMPLANTATION - Techniques for low temperature ion implantation are provided to improve the throughput. During a low temperature ion implantation, an implant process may be started before the substrate temperature is decreased to be about to a prescribed implant temperature by a cooling process, and a heating process may be started to increase the substrate temperature before the implant process is finished. Moreover, one or more temperature adjust process may be performed during one or more portion of the implant process, such that the substrate temperature may be controllably higher than the prescribe implant temperature during the implant process. | 05-10-2012 |
20120097861 | DECELERATION APPARATUS FOR RIBBON AND SPOT BEAMS - A deceleration apparatus capable of decelerating a short spot beam or a tall. ribbon beam is disclosed. In either case, effects tending to degrade the shape of the beam profile are controlled. Caps to shield the ion beam from external potentials are provided. Electrodes whose position and potentials are adjustable are provided, on opposite sides of the beam, to ensure that the shape of the decelerating and deflecting electric fields does not significantly deviate from the optimum shape, even in the presence of the significant space-charge of high current low-energy beams of heavy ions. | 04-26-2012 |
20120085936 | METHOD FOR MONITORING ION IMPLANTATION - A method capable of monitoring ion implantation. First, an ion beam and a workpiece are provided. Next, implant the workpiece by the ion beam and generate a profile having numerous signals relevant to respectively numerous relative positions between the ion beam and the workpiece, wherein the profile has at least a higher portion, a gradual portion and a lower portion. Therefore, by directly analyzing the profile without referring to a pre-determined profile and without using a profiler measuring the ion beam, some ion beam information may be acquired, such as beam height, beam width, ion beam current distribution on the ion beam cross-section, and so on, and the ion implantation may be monitored real-timely. Furthermore, when numerous workpieces are implanted in sequence, the profile(s) of one or more initially implanted workpiece(s) may be to generate a reference for calibrating the ion implantation of the following workpieces. | 04-12-2012 |
20120061560 | ION IMPLANTING SYSTEM - An ion implanting system includes an ion beam generator configured for generating a first ion beam; a mass separation device configured for isolating a second ion beam including required ions from the first ion beam; a holder device configured for holding a plurality of substrates, wherein the holder device and the second ion beam reciprocate relative to each other along a first direction to make the plurality of substrates pass across a projection region of the second ion beam; and a first detector configured for obtaining relevant parameters of the second ion beam. The above ion beam implanting system may increase the ion beam utilization rate. The ion implanting system further comprises a second detector arranged on the holder device which could fully scan across the projection range of the second ion beam and obtaining the relevant parameters of the second ion beam. | 03-15-2012 |
20120019257 | APPARATUS AND METHOD FOR MEASURING ION BEAM CURRENT - Techniques for ion beam current measurement, especially for measuring low energy ion beam current, are disclosed. In one exemplary embodiment, the techniques may be realized as an ion beam current measurement apparatus has at least a planar Faraday cup and a magnet device. The planar Faraday cup is close to an inner surface of a chamber wall, and may be non-parallel to or parallel to the inner surface. The magnet device is located close to the planar Faraday cup. Therefore, by properly adjusting the magnetic field, secondary electrons, incoming electrons and low energy ions may be adequately suppressed. Further, the planar Faraday cup may surround an opening of an additional Faraday cup being any conventional Faraday cup. Therefore, the whole ion beam may be received and measured well by the larger cross-section area of at least the planar Faraday cup on the ion beam path. | 01-26-2012 |
20110244669 | METHOD FOR LOW TEMPERATURE ION IMPLANTATION - Techniques for low temperature ion implantation are provided to improve the throughput. During a low temperature ion implantation, an implant process may be started before the substrate temperature is decreased to be about to a prescribed implant temperature by a cooling process, and a heating process may be started to increase the substrate temperature before the implant process is finished. Moreover, one or more temperature adjust process may be performed during one or more portion of the implant process, such that the substrate temperature may be controllably higher than the prescribe implant temperature during the implant process. | 10-06-2011 |
20110229987 | METHOD FOR LOW TEMPERATURE ION IMPLANTATION - Techniques for low temperature ion implantation are provided to improve throughput. Specifically, the pressure of the backside gas may temporarily, continually or continuously increase before the starting of the implant process, such that the wafer may be quickly cooled down from room temperature to be essentially equal to the prescribed implant temperature. Further, after the vacuum venting process, the wafer may wait an extra time in the load lock chamber before the wafer is moved out the ion implanter, in order to allow the wafer temperature to reach a higher temperature quickly for minimizing water condensation on the wafer surface. Furthermore, to accurately monitor the wafer temperature during a period of changing wafer temperature, a non-contact type temperature measuring device may be used to monitor wafer temperature in a real time manner with minimized condensation. | 09-22-2011 |
20110089334 | ION IMPLANTER WITH VARIABLE APERTURE AND ION IMPLANT METHOD THEREOF - An ion implanter and an ion implant method are disclosed. The ion implanter has an aperture assembly with a variable aperture and is located between an ion source of an ion beam and a holder for holding a wafer. At least one of the size and the shape of the variable aperture is adjustable. The ion beam may be flexibly shaped by the variable aperture, so that the practical implantation on the wafer can be controllably adjusted without modifying an operation of both the ion source and mass analyzer or applying a magnetic field to modify the ion beam. An example of the aperture assembly has two plates, each having an opening formed on its edge such that a variable aperture is formed by a combination of these openings. By respectively moving the plates, the size and the shape of the variable aperture can be changed. | 04-21-2011 |
20110068277 | BEAM CONTROL ASSEMBLY FOR RIBBON BEAM OF IONS FOR ION IMPLANTATION - A beam control assembly to shape a ribbon beam of ions for ion implantation includes a first bar, second bar, first coil of windings of electrical wire, second coil of windings of electrical wire, first electrical power supply, and second electrical power supply. The first coil is disposed on the first bar. The first coil is the only coil disposed on the first bar. The second bar is disposed opposite the first bar with a gap defined between the first and second bars. The ribbon beam travels between the gap. The second coil is disposed on the second bar. The second coil is the only coil disposed on the second bar. The first electrical power supply is connected to the first coil without being electrically connected to any other coil. The second electrical power supply is connected to the second coil without being electrically connected to any other coil. | 03-24-2011 |
20110049383 | ION IMPLANTER AND ION IMPLANT METHOD THEREOF - An ion implanter and an ion implant method for achieving a two-dimensional implantation on a wafer are disclosed. The ion implanter includes an ion source, a mass analyzer, a wafer driving mechanism, an aperture mechanism, and an aperture driving mechanism. The ion source and the mass analyzer are capable of providing an ion beam. The wafer driving mechanism is configured to drive a wafer along only a first direction. The aperture mechanism has an aperture for filtering the ion beam before the wafer is implanted. The aperture driving mechanism is configured to drive the aperture along a second direction intersecting the first direction. By moving the wafer and the aperture along different directions separately, the projection of the ion beam can achieve a two-dimensional implantation on the wafer. Here, at least one of the directions is optionally parallel to the longer dimension of the two-dimensional cross-section of the ion beam. | 03-03-2011 |
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 |
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 |
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 |
20080230712 | BEAM CONTROL ASSEMBLY FOR RIBBON BEAM OF IONS FOR ION IMPLANTATION - A beam control assembly to shape a ribbon beam of ions for ion implantation includes a first bar, second bar, first coil of windings of electrical wire, second coil of windings of electrical wire, first electrical power supply, and second electrical power supply. The first coil is disposed on the first bar. The first coil is the only coil disposed on the first bar. The second bar is disposed opposite the first bar with a gap defined between the first and second bars. The ribbon beam travels between the gap. The second coil is disposed on the second bar. The second coil is the only coil disposed on the second bar. The first electrical power supply is connected to the first coil without being electrically connected to any other coil. The second electrical power supply is connected to the second coil without being electrically connected to any other coil. | 09-25-2008 |