Abstract: An ion source has an arc chamber defining an arc chamber volume. A reservoir is coupled to the arc chamber, defining a reservoir volume. The reservoir receives a source species to define a liquid within the reservoir volume. A conduit fluidly couples the reservoir volume to the arc chamber volume. First and second openings of the conduit are open to the respective reservoir and arc chamber volume. A heat source selectively heats the reservoir to melt the source species at a predetermined temperature. A liquid control apparatus controls a first volume of the liquid within the reservoir volume to define a predetermined supply of the liquid to the arc chamber volume. The liquid control apparatus is a pressurized gas source fluidly coupled to the reservoir to supply a gas to the reservoir and provide a predetermined amount of liquid to the arc chamber.

Abstract: An ion source has an arc chamber defining an arc chamber volume. A reservoir is coupled to the arc chamber, defining a reservoir volume. The reservoir receives a source species to define a liquid within the reservoir volume. A conduit fluidly couples the reservoir volume to the arc chamber volume. First and second openings of the conduit are open to the respective reservoir and arc chamber volume. A heat source selectively heats the reservoir to melt the source species at a predetermined temperature. A liquid control apparatus controls a first volume of the liquid within the reservoir volume to define a predetermined supply of the liquid to the arc chamber volume. The liquid control apparatus is a pressurized gas source fluidly coupled to the reservoir to supply a gas to the reservoir and provide a predetermined amount of liquid to the arc chamber.

Abstract: An ion source has an arc chamber defining an arc chamber volume. A reservoir is coupled to the arc chamber, defining a reservoir volume. The reservoir receives a source species to define a liquid within the reservoir volume. A conduit fluidly couples the reservoir volume to the arc chamber volume. First and second openings of the conduit are open to the respective reservoir and arc chamber volume. A heat source selectively heats the reservoir to melt the source species at a predetermined temperature. A liquid control apparatus controls a first volume of the liquid within the reservoir volume to define a predetermined supply of the liquid to the arc chamber volume. The liquid control apparatus is a pressurized gas source fluidly coupled to the reservoir to supply a gas to the reservoir and provide a predetermined amount of liquid to the arc chamber.

Abstract: An ion source for an ion implantation system is configured to form an ion beam from a predetermined species along a beamline, where the ion beam is at an initial energy. A deceleration component is configured to decelerate the ion beam to a final energy that is less than the initial energy. A workpiece support is configured to support a workpiece along a workpiece plane downstream of the deceleration component along the beamline. A beamline component is positioned downstream of the deceleration component along the beamline. The beamline component has a feature that is at least partially impinged by the ion beam, and where the feature has a surface having a predetermined angle of incidence with respect to the ion beam. The predetermined angle of incidence provides a predetermined sputter yield of the ion beam at the final energy that mitigates deposition of the ion species on the beamline component.

Abstract: A system and method for varying the temperature of a faceplate for an ion source is disclosed. The faceplate is held against the chamber walls of the ion source by a plurality of fasteners. These fasteners may include tension springs or compression springs. By changing the length of the tension spring or compression spring when under load, the spring force of the spring can be increased. This increased spring force increases the compressive force between the faceplate and the chamber walls, creating improved thermal conductivity. In certain embodiments, the length of the spring is regulated by an electronic length adjuster. This electronic length adjuster is in communication with a controller that outputs an electrical signal indicative of the desired length of the spring. Various mechanisms for adjusting the length of the spring are disclosed.

Abstract: A system and method for varying the temperature of a faceplate for an ion source is disclosed. The faceplate is held against the chamber walls of the ion source by a plurality of fasteners. These fasteners may include tension springs or compression springs. By changing the length of the tension spring or compression spring when under load, the spring force of the spring can be increased. This increased spring force increases the compressive force between the faceplate and the chamber walls, creating improved thermal conductivity. In certain embodiments, the length of the spring is regulated by an electronic length adjuster. This electronic length adjuster is in communication with a controller that outputs an electrical signal indicative of the desired length of the spring. Various mechanisms for adjusting the length of the spring are disclosed.

Abstract: A system for extending the life of insulating components disposed within a housing, such as an ion implanter, is disclosed. The system includes one or more insulating components, disposed in the housing, which are coated with a diamond like carbon (DLC) coating. The insulating components may be bushings or any insulating component used to electrically isolate two components having different voltage potentials, such as electrodes. This DLC coating retards the deposition of metals, such as those contained in the ion source, on the insulating components. This reduces the likelihood or electrical arcing or other phenomenon that affect the useful life of these insulating component.

Abstract: The IHC ion source comprises an ion source chamber having a cathode and a repeller on opposite ends. The ion source chamber is constructed of a ceramic material having very low electrical conductivity. An electrically conductive liner may be inserted into the ion source chamber and may cover three sides of the ion source chamber. The liner may be electrically connected to the faceplate, which contains the extraction aperture. The electrical connections for the cathode and repeller pass through apertures in the ceramic material. In this way, the apertures may be made smaller than otherwise possible as there is no risk of arcing. In certain embodiments, the electrical connections are molded into the ion source chamber or are press fit in the apertures. Further, the ceramic material used for the ion source chamber is more durable and introduces less contaminants to the extracted ion beam.

Abstract: The IHC ion source comprises an ion source chamber having a cathode and a repeller on opposite ends. The ion source chamber is constructed of a ceramic material having very low electrical conductivity. An electrically conductive liner may be inserted into the ion source chamber and may cover three sides of the ion source chamber. The liner may be electrically connected to the faceplate, which contains the extraction aperture. The electrical connections for the cathode and repeller pass through apertures in the ceramic material. In this way, the apertures may be made smaller than otherwise possible as there is no risk of arcing. In certain embodiments, the electrical connections are molded into the ion source chamber or are press fit in the apertures. Further, the ceramic material used for the ion source chamber is more durable and introduces less contaminants to the extracted ion beam.

Abstract: The IHC ion source comprises an ion source chamber having a cathode and a repeller on opposite ends. The ion source chamber is constructed of a ceramic material having very low electrical conductivity. An electrically conductive liner may be inserted into the ion source chamber and may cover three sides of the ion source chamber. The liner may be electrically connected to the faceplate, which contains the extraction aperture. The electrical connections for the cathode and repeller pass through apertures in the ceramic material. In this way, the apertures may be made smaller than otherwise possible as there is no risk of arcing. In certain embodiments, the electrical connections are molded into the ion source chamber or are press fit in the apertures. Further, the ceramic material used for the ion source chamber is more durable and introduces less contaminants to the extracted ion beam.

Abstract: The IHC ion source comprises an ion source chamber having a cathode and a repeller on opposite ends. The ion source chamber is constructed of a ceramic material having very low electrical conductivity. An electrically conductive liner may be inserted into the ion source chamber and may cover three sides of the ion source chamber. The liner may be electrically connected to the faceplate, which contains the extraction aperture. The electrical connections for the cathode and repeller pass through apertures in the ceramic material. In this way, the apertures may be made smaller than otherwise possible as there is no risk of arcing. In certain embodiments, the electrical connections are molded into the ion source chamber or are press fit in the apertures. Further, the ceramic material used for the ion source chamber is more durable and introduces less contaminants to the extracted ion beam.

Abstract: A system and method of improving the performance and extending the lifetime of an ion source is disclosed. The ion source includes an ion source chamber, a suppression electrode and a ground electrode. In the processing mode, the ion source chamber may be biased to a first positive voltage, while the suppression electrode is biased to a negative voltage to attract positive ions from within the chamber through an aperture and toward the workpiece. In the cleaning mode, the ion source chamber may be grounded, while the suppression electrode is biased using a power supply having a high current capability. The voltage applied to the suppression electrode creates a plasma between the suppression electrode and the ion source chamber, and between the suppression electrode and the ground electrode.

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 apparatus for controlling the temperature of an ion source is disclosed. The ion source includes a plurality of walls defining a chamber in which ions are generated. To control the temperature of the ion source, one or more heat shields is disposed exterior to the chamber. The heat shields are made of high temperature and/or refractory material designed to reflect heat back toward the ion source. In a first position, these heat shields are disposed to reflect a first amount of heat back toward the ion source. In a second position, these heat shields are disposed to reflect a lesser second amount of heat back toward the ion source. In some embodiments, the heat shields may be disposed in one or more intermediate positions, located between the first and second positions.

Abstract: An ion implantation system, having a temperature controlled ion source chamber is disclosed. The temperature of the ion source chamber is regulated by disposing a heat sink in proximity to the ion source chamber. A gas fillable chamber is disposed between and in physical communication with both the ion source chamber and the heat sink. By controlling the amount of gas, i.e. the gas pressure, within the gas fillable chamber, the coefficient of heat transfer can be manipulated. This allows the temperature of the ion source chamber to be controlled through the application or removal of gas from the gas fillable chamber. This independent temperature control decouples the power used to heat the ion generator from the ion species that are ultimately generated.

Abstract: An apparatus for controlling the temperature of an ion source is disclosed. The ion source includes a plurality of walls defining a chamber in which ions are generated. To control the temperature of the ion source, one or more heat shields is disposed exterior to the chamber. The heat shields are made of high temperature and/or refractory material designed to reflect heat back toward the ion source. In a first position, these heat shields are disposed to reflect a first amount of heat back toward the ion source. In a second position, these heat shields are disposed to reflect a lesser second amount of heat back toward the ion source. In some embodiments, the heat shields may be disposed in one or more intermediate positions, located between the first and second positions.

Abstract: A self-cleaning radio frequency (RF) plasma source for a semiconductor manufacturing process is described. Various examples provide an RF plasma source comprising an RF antenna and a rotatable dielectric sleeve disposed around the RF antenna. The dielectric is positioned between a process chamber and cleaning chamber such that portions of the surface of the dielectric may be exposed to either the process chamber or the cleaning chamber. As material is deposited on the outer surface of the dielectric in the process chamber, the dielectric sleeve is rotated so that the portion containing the buildup is exposed to the cleaning chamber. A sputtering process in the cleaning chamber removes the buildup from the surface of the sleeve. The dielectric sleeve is then rotated so that it exposed to the process chamber. Other embodiments are disclosed and claimed.

Abstract: A method and apparatus are disclosed for controlling a semiconductor process temperature. In one embodiment a thermal control device includes a heat source and a housing comprising a vapor chamber coupled to the heat source. The vapor chamber includes an evaporator section and a condenser section. The evaporator section has a first wall associated with the heat source, the first wall having a wick for drawing a working fluid from a lower portion of the vapor chamber to the evaporator section. The condenser section coupled to a cooling element. The vapor chamber is configured to transfer heat from the heat source to the cooling element via continuous evaporation of the working fluid at the evaporator section and condensation of the working fluid at the condenser section. Other embodiments are disclosed and claimed.

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: An ion implantation system, having a temperature controlled ion source chamber is disclosed. The temperature of the ion source chamber is regulated by disposing a heat sink in proximity to the ion source chamber. A gas fillable chamber is disposed between and in physical communication with both the ion source chamber and the heat sink. By controlling the amount of gas, i.e. the gas pressure, within the gas fillable chamber, the coefficient of heat transfer can be manipulated. This allows the temperature of the ion source chamber to be controlled through the application or removal of gas from the gas fillable chamber. This independent temperature control decouples the power used to heat the ion generator from the ion species that are ultimately generated.