摘要:
A system for inhibiting the transport of contaminant particles with an ion beam includes a pair of electrodes that provide opposite electric fields through which the ion beam travels. A particle entrained in the ion beam is charged to a polarity matching the polarity of ion beam when traveling through a first of the electric fields. The downstream electrode provides another electric field for repelling the positively charged particle away from the direction of beam travel.
摘要:
A system for inhibiting the transport of contaminant particles with an ion beam includes a particle charging system for charging particles within a region through which the ion beam travels. An electric field is generated downstream relative to the charged region so as to urge charged particles away from a direction of travel for the ion beam.
摘要:
A magnetic deflector for an ion beam is disclosed and comprises first and second coils. The coils are positioned above and below the beam, respectively, and extend along a width of the beam. Current passes through the coils to generate a magnetic field therebetween that is generally perpendicular to a direction of travel of the beam along substantially the entire width thereof. In another aspect of the invention, a method of deflecting a beam prior to implantation into a workpiece is disclosed. The method includes determining one or more properties associated with the beam and selectively activating one of a magnetic deflection module and an electrostatic deflection module based on the determination.
摘要:
A lens structure for use with an ion beam implanter. The lens structure includes first and second electrodes spaced apart along a direction of ion movement. The lens structure extends across a width of the ion beam for deflecting ions entering the lens structure. The lens structure includes a first electrode for decelerating ions and a second electrode for accelerating the ions. A lens structure mode controller selectively activates either the accelerating or decelerating electrode to to cause ions entering the lens structure to exit said lens structure with a desired trajectory regardless of the trajectory ions enter the lens structure.
摘要:
A lens structure for use with an ion beam implanter. The lens structure includes first and second electrodes spaced apart along a direction of ion movement. The lens structure extends on opposite sides of a beam path across a width of the ion beam for deflecting ions entering the lens structure. The lens structure include a first electrode for decelerating ions and a second electrode for accelerating the ions to cause ions entering the lens structure to exit said lens structure with approximately the same exit trajectory regardless of the trajectory ions enter the lens structure. In an alternate construction the lens structure can include a first electrode for accelerating ions and a second electrode for decelerating ions.
摘要:
A system for inhibiting the transport of contaminant particles with an ion beam includes an electric field generator for generating an electric field relative to a path of travel for the ion beam. A particle located in the ion beam and in a region of the electric field is charged to a polarity according to the ion beam, so that the electric field may urge the charged particle out of the ion beam.
摘要:
A focusing particle trap system for ion implantation comprising an ion beam source that generates an ion beam, a beam line assembly that receives the ion beam from the ion beam source comprising a mass analyzer that selectively passes selected ions, a focusing electrostatic particle trap that receives the ion beam and removes particles from the ion beam comprising an entrance electrode comprising an entrance aperture and biased to a first base voltage, wherein the first surface of the entrance electrode is facing away from a center electrode and is approximately flat, wherein the second surface of the entrance electrode is facing toward the center electrode and is concave, wherein the center electrode is positioned a distance downstream from the entrance electrode comprising a center aperture and biased to a center voltage, wherein the center voltage is less than the first base voltage, wherein the first surface of the center electrode is facing toward the entrance electrode and is convex, wherein the second surface of the center electrode is facing away from the entrance electrode and is approximately flat, an exit electrode positioned a distance downstream from the center electrode comprising an exit aperture and biased to a second base voltage, and wherein the first surface of the exit electrode is facing toward the center electrode and is approximately flat, wherein the second surface of the exit electrode is facing away from the center electrode and is approximately flat, wherein a first electrostatic field is generated from the entrance electrode toward the center electrode and a second electrostatic field is generated from the exit electrode toward the center electrode; wherein the second base voltage is greater than the center voltage, and an end station that is downstream from the beam line assembly and receives the ion beam.
摘要:
A method and system for in-process cleaning of an ion source (12) is provided. The ion source (12) comprises (i) a plasma chamber (22) formed by chamber walls (112, 114, 116) that bound an ionization zone (120); (ii) a source of ionizable dopant gas (66) and a first mechanism (68) for introducing said ionizable dopant gas into said plasma chamber; (iii) a source of cleaning gas (182) and a second mechanism (184) for introducing said cleaning gas into said plasma chamber; and (iv) an exciter (130) at least partially disposed within said chamber for imparting energy to said ionizable dopant gas and said cleaning gas to create a plasma within said plasma chamber. The plasma comprises disassociated and ionized constituents of said dopant gas and disassociated and ionized constituents of said cleaning gas. The disassociated and ionized constituents of said cleaning gas react with said disassociated and ionized constituents of said dopant gas to prevent formation of deposits of elements contained within said ionizable dopant gas on surfaces of said chamber walls. The cleaning gas may be, for example, nitrogen trifluoride (NF.sub.3), and the ionizable dopant gas may be, for example, either phosphine (PH.sub.3) or arsine (AsH.sub.3). Mass flow controllers control the ratio of cleaning gas to ionizable dopant gas introduced into said plasma chamber, which is greater than 0:1 and preferably at least 3:1.
摘要:
An ion implantation cluster tool for implanting ions into a workpiece is provided, wherein a plurality of beamline assemblies having a respective plurality of ion beamlines associated therewith are positioned about a common process chamber. Each of the plurality of ion beamline assemblies are selectively isolated from the common process chamber, and the plurality of beamline intersect at a processing region of the process chamber. A scanning apparatus positioned within the common process chamber is operable to selectively translate a workpiece holder in one or more directions through each of the plurality of ion beamlines within the processing region, and a common dosimetry apparatus within the common process chamber is operable to measure one or more properties of each of the plurality of ion beamlines. A load lock chamber is operably coupled to the common process chamber for exchange of workpieces between the common process chamber and an external environment.
摘要:
A device is disclosed for providing an inductively coupled radio frequency plasma flood gun. In one particular exemplary embodiment, the device is a plasma flood gun in an ion implantation system. The plasma flood gun may comprise a plasma chamber having one or more apertures; a gas source capable of supplying at least one gaseous substance to the plasma chamber; a single-turn coil disposed within the plasma chamber, and a power source coupled to the coil for inductively coupling radio frequency electrical power to excite the at least one gaseous substance in the plasma chamber to generate a plasma. The inner surface of the plasma chamber may be free of metal-containing material and the plasma may not be exposed to any metal-containing component within the plasma chamber. The plasma chamber may include a plurality of magnets for controlling the plasma. An exit aperture may be provided in the plasma chamber to enable negatively charged particles of the resulting plasma to engage an ion beam that is part of the associated ion implantation system. In one embodiment, magnets are disposed on opposite sides of the aperture and are used to manipulate the electrons of the plasma.