Abstract: An ion implantation system for improving performance and extending lifetime of an ion source is disclosed. A fluorine-containing dopant gas source is introduced into the ion chamber along with one or more co-gases. The one or more co-gases can include hydrogen or krypton. The co-gases mitigate the effects caused by free fluorine ions in the ion source chamber which lead to ion source failure.

Abstract: An ion implantation system has a first chamber and a process chamber with a heated chuck. A controller transfers the workpiece between the heated chuck and first chamber and selectively energizes the heated chuck first and second modes. In the first and second modes, the heated chuck is heated to a first and second temperature, respectively. The first temperature is predetermined. The second temperature is variable, whereby the controller determines the second temperature based on a thermal budget, an implant energy, and/or an initial temperature of the workpiece in the first chamber, and generally maintains the second temperature in the second mode. Transferring the workpiece from the heated chuck to the first chamber removes implant energy from the process chamber in the second mode. Heat may be further transferred from the heated chuck to a cooling platen by a transfer of the workpiece therebetween to sequentially cool the heated chuck.

Abstract: An ion source has an arc chamber having a body defining and interior region. A liner defined an exposure surface of the interior region that is exposed to a plasma generated within the arc chamber. An electrode has a shaft with a first diameter that passes through the body and the liner. The electrode is electrically isolated from the body where the liner is a plate having a first surface with an optional recess having a second surface. A hole is defined through the recess for the shaft to pass through. The hole has a second diameter that is larger than the first diameter, and an annular gap exists between the plate and the shaft. The plate has a lip extending from the second surface toward the first surface that surrounds the hole within the recess and generally prevents particulate contaminants from entering the annular gap.

Abstract: A resolving aperture assembly for an ion implantation system has a first plate and a second plate, where the first plate and second plate generally define a resolving aperture therebetween. A position of the first plate with respect to the second plate generally defines a width of the resolving aperture. One or more actuators are operably coupled to one or more of the first plate and second plate and are configured to selectively vary the position the first plate and second plate with respect to one another, thus selectively varying the width of the resolving aperture. A servo motor precisely varies the resolving aperture width and a pneumatic cylinder independently selectively closes the resolving aperture. A downstream position actuator varies a position of the resolving aperture along a path of the ion beam, and a controller controls the one or more actuators based on desired properties of the ion beam.

Abstract: An electrostatic chuck and gripping system are configured for clamping and processing workpieces having differing diameters. An ion implantation apparatus selectively provides ions to a first workpiece and a second workpiece in a process chamber, where a diameter of the first workpiece is greater the second workpiece. A chuck supports the respective first or second workpiece within the process chamber during exposure to the ions. A load lock chamber isolates a process environment from an external environment and has a workpiece support for the respective first or second workpiece during a transfer of the first or second workpiece between the process chamber and the external environment. A vacuum robot transfers the first or second workpiece between the chuck and workpiece support, and has a gripper mechanism configured to selectively grip the first or second workpiece between a plurality of stepped guides.

Abstract: An optics plate for an ion implantation system, the optics plate comprising a pair of aperture assemblies. Each pair of aperture assemblies respectively comprises a first aperture member, a second aperture member; and an aperture fastener, wherein the aperture fastener fastens the first aperture member to the second aperture member. An aperture tip may be also fastened to the second aperture member. One or more of the first aperture member, second aperture member, aperture tip, and aperture fastener is made of one or more of a refractory metal, tungsten, lanthanated tungsten alloy, yttrium tungsten alloy, and/or graphite and silicon carbide. The aperture assemblies may define an extraction electrode assembly, a ground electrode assembly, or other electrode assembly in the ion implantation system. The aperture fastener may be a screw and a bevel washer. The first aperture member may be operably coupled to a base plate via an aperture assembly fastener.

Abstract: A system and method for clamping a workpiece to an electrostatic clamp (ESC) comprises placing a first workpiece on a surface of the ESC and applying a first set of clamping parameters to the ESC, therein clamping the first workpiece to the surface of the ESC with a first clamping force. A degree of clamping of the workpiece to the ESC is determined and the application of the first set of clamping parameters to the ESC is halted based on a process recipe. A second set of clamping parameters is applied to the ESC after halting the application of the first set of clamping parameters to the ESC, and the workpiece is removed from the surface of the ESC concurrent with the application of the second set of clamping parameters to the ESC when the degree of clamping of the workpiece to the ESC is less than or approximately equal to a threshold clamping value. The second set of clamping parameters to the ESC is further halted after removing the workpiece from the surface of the ESC.

Abstract: A workpiece support has a vessel having a top interior wall and a bottom interior wall. An interior cavity is defined between the top interior wall and bottom interior wall, wherein a support surface configured to support a workpiece. A plate is positioned within the interior cavity, dividing the interior cavity into a top cavity and a bottom cavity. The top and bottom cavities are fluidly coupled about a periphery of the plate. A first taper defined in one or more of the top interior wall and a top portion of the plate provides a substantially constant volume across a radial cross-section of the top cavity. A second taper defined in one or more of the bottom interior wall and a bottom portion of the plate provides a substantially constant volume across a radial cross-section of the bottom cavity. First and second ports fluidly couple the top and bottom cavities to respective first and second fluid channels.

Abstract: A semiconductor manufacturing system or process, such as an ion implantation system, apparatus and method, including a component or step for heating a semiconductor workpiece are provided. An optical heat source emits light energy to heat the workpiece. The optical heat source is configured to provide minimal or reduced emission of non-visible wavelengths of light energy and emit light energy at a wavelength in a maximum energy light absorption range of the workpiece.

Abstract: A system, apparatus and method for increasing ion source lifetime in an ion implanter are provided. Oxidation of the ion source and ion source chamber poisoning resulting from a carbon and oxygen-containing source gas is controlled by utilizing a hydrogen co-gas, which reacts with free oxygen atoms to form hydroxide and water.

Abstract: 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.

Abstract: An ion implantation system provides ions to a workpiece positioned in a process environment of a process chamber on a sub-ambient temperature chuck. An intermediate chamber having an intermediate environment is in fluid communication with an external environment and has a cooling station and heating station for cooling and heating the workpiece. A load lock chamber is provided between the process chamber and intermediate chamber to isolate the process environment from the intermediate environment. A positive pressure source provides a dry gas within the intermediate chamber at dew point that is less than a dew point of the external environment to the intermediate chamber. The positive pressure source isolates the intermediate environment from the external environment via a flow of the dry gas from the intermediate chamber to the external environment.

Abstract: A system and method are provided for implanting ions at low energies into a workpiece. An ion source configured to generate an ion beam is provided, wherein a mass resolving magnet is configured to mass resolve the ion beam. The ion beam may be a ribbon beam or a scanned spot ion beam. A mass resolving aperture positioned downstream of the mass resolving magnet filters undesirable species from the ion beam. A combined electrostatic lens system is positioned downstream of the mass analyzer, wherein a path of the ion beam is deflected and contaminants are generally filtered out of the ion beam, while concurrently decelerating and parallelizing the ion beam. A workpiece scanning system is further positioned downstream of the combined electrostatic lens system, and is configured to selectively translate a workpiece in one or more directions through the ion beam, therein implanting ions into the workpiece.

Abstract: An electrostatic clamp (ESC) has a clamping surface, and first and second pairs of electrodes. Each of the first pair of electrodes are associated with a respective third of the clamping surface, and each of the second pair of electrodes are associated with a respective sixth of the clamping surface. A peripheral region of each of the first and second pairs of electrodes spirals toward the periphery of the clamping surface. A DC mode connects one of each of the first and second pair of electrodes to a positive and the other one of the respective first and second pair of electrodes to a negative of a power supply. An AC mode electrically connects first, second, and third phase terminals of the power supply to one of the first pair of electrodes, the other one of the first pair of electrodes, and both of the second pair of electrodes, respectively.

Abstract: A combined scanning and focusing magnet for an ion implantation system is provided. The combined scanning and focusing magnet has a yoke having a high magnetic permeability. The yoke defines a hole configured to pass an ion beam therethrough. One or more scanner coils operably are coupled to the yoke and configured to generate a time-varying predominantly dipole magnetic field when electrically coupled to a power supply. One or more focusing coils are operably coupled to the yoke and configured to generate a predominantly multipole magnetic field, wherein the predominantly multipole magnetic field is one of static or time-varying.

Abstract: An end station for an ion implantation system is provided, wherein the end station comprises a process chamber configured to receive an ion beam. A load lock chamber is coupled to the process chamber and configured to selectively introduce a workpiece into the process chamber. An electrostatic chuck within the process chamber is configured to selectively translate through the ion beam, and a shield within the process chamber is configured to selectively cover at least a portion of a clamping surface of the electrostatic chuck to protect the clamping surface from one or more contaminants associated with the ion beam. A docking station within the process chamber selectively retains the shield, and a transfer mechanism is configured to transfer a workpiece between the load lock chamber and the electrostatic chuck, and to transfer the shield between the docking station and the clamping surface of the electrostatic chuck.

Abstract: An ion implantation system has a process chamber having a process environment, and an ion implantation apparatus configured to implant ions into a workpiece supported by a chuck within the process chamber. A load lock chamber isolates the process (vacuum) environment from an atmospheric environment, wherein a load lock workpiece support supports the workpiece therein. An isolation chamber is coupled to the process chamber with a pre-implant cooling environment defined therein. An isolation gate valve selectively isolates the pre-implant cooling environment from the process environment wherein the isolation chamber comprises a pre-implant cooling workpiece support for supporting and cooling the workpiece. The isolation gate valve is the only access path for the workpiece to enter and exit the isolation chamber. A pressurized gas selectively pressurizes the pre-implant cooling environment to a pre-implant cooling pressure that is greater than the process pressure for expeditious cooling of the workpiece.

Abstract: Aspects of the present invention relate to ion implantation systems that make use of a vapor compression cooling system. In one embodiment, a thermal controller in the vapor compression system sends refrigeration fluid though a compressor and a condenser according to an ideal vapor compression cycle to help limit or prevent undesired heating of a workpiece during implantation, or to actively cool the workpiece.

Abstract: A charge monitor having a Langmuir probe is provided, wherein a positive and negative charge rectifier are operably coupled to the probe and configured to pass only a positive and negative charges therethrough, respectively. A positive current integrator is operably coupled to the positive charge rectifier, wherein the positive current integrator is biased via a positive threshold voltage, and wherein the positive current integrator is configured to output a positive dosage based, at least in part, on the positive threshold voltage. A negative current integrator is operably coupled to the negative charge rectifier, wherein the negative current integrator is biased via a negative threshold voltage, and wherein the negative current integrator is configured to output a negative dosage based, at least in part, on the negative threshold voltage.

Abstract: An ion source chamber for ion implantation system includes a housing that at least partially bounds an ionization region through which high energy electrons move from a cathode to ionize gas molecules injected into an interior of the housing; a liner section defining one or more interior walls of the housing interior, wherein each liner section includes a interiorly facing surface exposed to the ionization region during operation the ion implantation system; a cathode shield disposed about the cathode; a repeller spaced apart from the cathode; a plate including a source aperture for discharging ions from the ion source chamber; wherein at least one of the repeller, the liner section, the cathode shield; the plate, or an insert in the plate defining the source aperture comprise silicon carbide, wherein the silicon carbide is a non-stoichiometric sintered material having excess carbon.