Provided herein are approaches for reducing particles in an ion implanter. In some embodiments, an electrostatic filter of the ion implanter may include a housing and a plurality of conductive beam optics within the housing, the plurality of conductive beam optics arranged around an ion beam-line. At least one conductive beam optic of the plurality of conductive beam optics may include a conductive core element, a resistive material disposed around the conductive core, and a conductive layer disposed around the resistive material.

A cleaning tool for cleaning a glass surface of an accelerator column is disclosed. The cleaning tool includes a shaft including a first end and a second end; a foam body located at the first end of the shaft; and a mounting bracket coupled to the first end of the shaft, the mounting bracket receiving the foam body. An outer circumference of the foam body includes a textured cleaning surface for contacting the glass surface of the accelerator column.

The present disclosure describes a system and a method for providing a mixed gas to an ion implantation tool. The system includes a water supply, an electrical source, a gas generator. The gas generator is configured to generate a first gas from the water supply and the electrical source. The system also includes a first flow controller configured to control a first flow rate of the first gas, a gas container to provide a second gas, a second flow controller configured to control a second flow rate of the second gas, and a gas pipe configured to mix the first and second gases into a mixed gas. The mixed gas can he delivered to, for example, an ion source head of the ion implantation tool.

An ion source assembly and method has a source gas supply to provide a molecular carbon source gas to an ion source chamber. A source gas flow controller controls flow of the molecular carbon source gas to the ion source chamber. An excitation source excites the molecular carbon source gas to form carbon ions and radicals. An extraction electrode extracts the carbon ions from the ion source chamber, forming an ion beam. An oxidizing co-gas supply provides oxidizing co-gas to chamber. An oxidizing co-gas flow controller controls flow of the oxidizing co-gas to the chamber. The oxidizing co-gas decomposes and reacts with carbonaceous residues and atomic carbon forming carbon monoxide and carbon dioxide within the ion source chamber. A vacuum pump system removes the carbon monoxide and carbon dioxide, where deposition of atomic carbon within the ion source chamber is reduced and a lifetime of the ion source is increased.

An ion implantation system has a source that generates ions from a beam species to form an ion beam, and a mass analyzer mass analyzes the ion beam. An accelerator receives the ion beam having ions at a first charge state and exits the ion beam having ions at a second positive charge state. The accelerator has a charge stripper, a gas source, and a plurality of accelerator stages. The charge stripper converts the ions from the first charge state to the second charge state. The gas source provides a high molecular weight gas, such as hexafluoride, to the charge stripper, and the plurality of accelerator stages respectively accelerate the ions. An end station supports a workpiece to be implanted with ions at the second charge state.

An implantation device, an implantation system and a method. The implantation device comprises a filter frame and a filter held by the filter frame, wherein said filter is designed to be irradiated by an ion beam.

An ion source for an ion implantation system has a plurality of arc chambers. The ion source forms an ion beam from a respective one of the plurality of arc chambers based on a position of the respective one of the plurality of arc chambers with respect to a beamline. The arc chambers are coupled to a carrousel that translates or rotates the respective one of the plurality of arc chambers to a beamline position associated with the beamline. One or more of the plurality of arc chambers can have at least one unique feature, or two or more of the plurality of arc chambers can be generally identical to one another.

The disclosure discloses an ion injecting device, and an ion injecting method thereof, where the ion injecting device is modified by adding a vacant baffle between a process chamber and an analyzing magnet. Moreover the vacant baffle is closed before an engineer opens the process chamber for cleaning, so that the process chamber is separated from the analyzing magnet, thus maintaining a vacuum environment in the analyzing magnet. Subsequently only a vacuum environment in the process chamber will be created again.

An ion implanter. The ion implanter may include a beamline, the beamline defining an inner wall, surrounding a cavity, the cavity arranged to conduct an ion beam. The ion implanter may also include a low emission insert, disposed on the inner wall, and further comprising a .sup.12C layer, the .sup.12C layer having an outer surface, facing the cavity.

An apparatus is provided. The apparatus may include a main chamber; an entrance tunnel having a propagation axis extending into the main chamber along a first direction; an exit tunnel, connected to the main chamber and defining an exit direction. The entrance tunnel and the exit tunnel may define a beam bend of at least 30 degrees therebetween. The apparatus may include an electrode assembly, disposed in the main chamber, and defining a beam path between the entrance tunnel and the exit aperture, wherein the electrode assembly comprises a lower electrode, disposed on a first side of the beam path, and a plurality of electrodes, disposed on a second side of the beam path, the plurality of electrodes comprising at least five electrodes.