Abstract: Disclosed is a radio frequency (RF) antenna for plasma ion sources. The RF antenna includes a low-resistance metal tube having an inner and outer diameter. A low friction polymer tube also having an inner and outer diameter surrounds the low-resistance metal tube. The inner diameter of the polymer tube is slightly larger than the outer diameter of the low-resistance metal tube. A pre-formed quartz glass tube encases the low friction polymer tube and low-resistance metal tube. The quartz glass tube is pre-formed in a desired shape. A guide wire is attached inside one end of the low-resistance hollow metal tube. The flexible low friction polymer tube containing the low-resistance metal tubed may then be threaded through the quartz glass tube.

Abstract: An ion source includes an ion chamber housing defining an ion source chamber, the ion chamber housing having a side with a plurality of apertures. The ion source also includes an antechamber housing defining an antechamber. The antechamber housing shares the side with the plurality of apertures with the ion chamber housing. The antechamber housing has an opening to receive a gas from a gas source. The antechamber is configured to transform the gas into an altered state having excited neutrals that is provided through the plurality of apertures into the ion source chamber.

Abstract: In one embodiment, a method for generating an ion beam having gallium ions includes providing at least a portion of a gallium compound target in a plasma chamber, the gallium compound target comprising gallium and at least one additional element. The method also includes initiating a plasma in the plasma chamber using at least one gaseous species and providing a source of gaseous etchant species to react with the gallium compound target to form a volatile gallium species.

Abstract: An improved plasma processing chamber is disclosed, wherein some or all of the components which are exposed to the plasma are made of, or coated with, titanium diborane. Titanium diborane has a hardness in excess of 9 mhos, making it less susceptible to sputtering. In addition, titanium diborane is resistant to fluoride and chlorine ions. Finally, titanium diborane is electrically conductive, and therefore the plasma remains more uniform over time, as charge does not build on the surfaces of the titanium diborane components. This results in improved workpiece processing, with less contaminants and greater uniformity. In other embodiments, titanium diborane may be used to line components within a beam line implanter.

Abstract: An ion source that utilizes exited and/or atomic gas injection is disclosed. In an ion beam application, the source gas can be used directly, as it is traditionally supplied. Alternatively or additionally, the source gas can be altered by passing it through a remote plasma source prior to being introduced to the ion source chamber. This can be used to create excited neutrals, heavy ions, metastable molecules or multiply charged ions. In another embodiment, multiple gasses are used, where one or more of the gasses are passed through a remote plasma generator. In certain embodiments, the gasses are combined in a single plasma generator before being supplied to the ion source chamber. In plasma immersion applications, plasma is injected into the process chamber through one or more additional gas injection locations. These injection locations allow the influx of additional plasma, produced by remote plasma sources external to the process chamber.

Abstract: Techniques for improving extracted ion beam quality using high-transparency electrodes are disclosed. In one particular exemplary embodiment, the techniques may be realized as an apparatus for ion implantation. The apparatus may comprise an ion source for generating an ion beam, wherein the ion source comprises a faceplate with an aperture for the ion beam to travel therethrough. The apparatus may also comprise a set of extraction electrodes comprising at least a suppression electrode and a high-transparency ground electrode, wherein the set of extraction electrodes may extract the ion beam from the ion source via the faceplate, and wherein the high-transparency ground electrode may be configured to optimize gas conductance between the suppression electrode and the high-transparency ground electrode for improved extracted ion beam quality.

Abstract: An ion source includes an arc chamber housing defining an arc chamber having an extraction aperture, and a wiper. The wiper is positioned within the arc chamber in a parked position and configured to be driven from the parked position to operational positions to clean the extraction aperture. A cleaning sub-assembly for an ion source includes a wiper configured to be positioned within an arc chamber of the ion source when in a parked position and driven from the parked position to operational positions to clean an extraction aperture of the ion source.

Abstract: An improved plasma processing chamber is disclosed, wherein some or all of the components which are exposed to the plasma are made of, or coated with, titanium diborane. Titanium diborane has a hardness in excess of 9 mhos, making it less susceptible to sputtering. In addition, titanium diborane is resistant to fluoride and chlorine ions. Finally, titanium diborane is electrically conductive, and therefore the plasma remains more uniform over time, as charge does not build on the surfaces of the titanium diborane components. This results in improved workpiece processing, with less contaminants and greater uniformity. In other embodiments, titanium diborane may be used to line components within a beam line implanter.

Abstract: A technique for ion implanting a target is disclosed. In accordance with one exemplary embodiment, the technique may be realized as a method for ion implanting a target, the method comprising: providing a predetermined amount of processing gas in an arc chamber of an ion source, the processing gas containing implant species and implant species carrier, where the implant species carrier may be one of O and H; providing a predetermined amount of dilutant into the arc chamber, wherein the dilutant may comprise a noble species containing material; and ionizing the processing gas and the dilutant.

Abstract: Liner elements to protect the ion source housing and also increase the power efficiency of the ion source are disclosed. Two liner elements, preferably constructed from tungsten, are inserted into the ion source chamber, one placed against each of the two sidewalls. These inserts are electrically biased so as to induce an electrical field that is perpendicular to the applied magnetic field. Such an arrangement has been unexpectedly found to increase the life of not only the ion chamber housing, but also the indirectly heated cathode (IHC) and the repeller. In addition, the use of these biased liner elements also improved the power efficiency of the ion source; allowing more ions to be generated at a given power level, or an equal number of ions to be generated at a lower power level.

Abstract: An apparatus and method for producing electrons in a plasma flood gun is disclosed. The apparatus includes an indirectly heated cathode (IHC) which is contained within a pre-fabricated cartridge. This cartridge can be readily replaced in a plasma flood gun. In addition, the use of an IHC reduces the amount of contaminants that are injected into the workpiece or wafer.

Abstract: In an ion implanter, an inert gas is directed at a cathode assembly near an ion source chamber via a supply tube. The inert gas is provided with a localized directional flow toward the cathode assembly to reduce unwanted concentrations of cleaning or dopant gases introduced into the ion source chamber, thereby reducing the effects of unwanted filament growth in the cathode assembly and extending the manufacturing life of the ion source.

Abstract: An apparatus includes an arc chamber housing defining an arc chamber, and a feed system configured to feed a sputter target into the arc chamber. A method includes feeding a sputter target into an arc chamber defined by an arc chamber housing, and ionizing a portion of the sputter target.

Abstract: An ion source includes an arc chamber housing defining an arc chamber having an extraction aperture, and a wiper assembly comprising a wiper positioned outside the arc chamber in a parked position and configured to be driven from the parked position to operational positions to clean the extraction aperture. A wiper assembly for an ion source includes a wiper configured to be positioned outside an arc chamber of the ion source when in a parked position and driven from the parked position to operational positions to clean an extraction aperture of the ion source.

Abstract: An ion source includes an arc chamber housing defining an arc chamber having an extraction aperture, and a wiper. The wiper is positioned within the arc chamber in a parked position and configured to be driven from the parked position to operational positions to clean the extraction aperture. A cleaning sub-assembly for an ion source includes a wiper configured to be positioned within an arc chamber of the ion source when in a parked position and driven from the parked position to operational positions to clean an extraction aperture of the ion source.

Abstract: An ion source includes an arc chamber housing defining an arc chamber having an extraction aperture, and a wiper assembly comprising a wiper positioned outside the arc chamber in a parked position and configured to be driven from the parked position to operational positions to clean the extraction aperture. A wiper assembly for an ion source includes a wiper configured to be positioned outside an arc chamber of the ion source when in a parked position and driven from the parked position to operational positions to clean an extraction aperture of the ion source.

Abstract: To implant a carbon-containing species, a gas containing carbon is ionized in the ion chamber. The ionization of this gas will typically produce a number of ionized species. However, many of these resulting ionized species are not beneficial to the desired implant, as they contain only non-carbon atoms. These species must be eliminated before the implantation, leaving only carbon-based species. However, the current of the desired species may be low, thereby requiring extra energy or time to implant the desired dosage of carbon into a substrate. This can be improved through the use of a second gas. This second gas is used to dilute the primary carbon-containing gas to be ionized in the ion chamber. By incorporating this dilution gas, more of the resulting ionized species are beneficial to the carbon implantation.

Abstract: In an ion implanter, a Faraday cup is utilized to receive an ion beam generated during ion source cleaning. The detected beam has an associated mass spectrum which indicates when the ion source cleaning process is complete. The mass spectrum results in a signal composed of a cleaning agent and the material comprising the ion source. This signal will rise over time as the ion source chamber is being cleaned and will level-off and remain constant once the deposits are etched away from the source chamber, thereby utilizing existing implant tools to determine endpoint detection during ion source cleaning.

Abstract: Herein an improved technique for generating uniform ion beam is disclosed. In one particular exemplary embodiment, the technique may be realized as a method for processing a substrate with an ion implanter comprising an ion source. The method may comprise: introducing dopant into an ion source chamber of the ion source, the dopant may comprise molecules containing boron and hydrogen; introducing diluent into the ion source chamber, the diluent containing halogen; ionizing the dopant and the diluent into molecular ions and halogen containing ions, the molecular ions containing boron and hydrogen; extracting the molecular ions and the halogen containing ions from the ions source chamber; and directing the molecular ions toward the substrate, where the halogen containing ions may improve uniformity of the molecular ions extracted from the ion source and extend the lifetime of the ion source.

Abstract: In a cleaning process for an ion source chamber, an electrode positioned outside of the ion source chamber includes a suppression plug. When the cleaning gas is introduced intothe source chamber, the suppression plug may engage an extraction aperture of the source chamber to adjust the gas pressure within the chamber to enhance chamber cleaning via. plasma-enhanced chemical reaction. The gas conductance between the source chamber aperture and the suppression plug can be adjusted during the cleaning process to provide optimum cleaning conditions and to exhaust unwanted deposits.