An ion generator includes: an arc chamber which defines a plasma generation space; a cathode which emits thermoelectrons toward the plasma generation space; and a repeller which faces the cathode with the plasma generation space interposed therebetween. The arc chamber includes a box-shaped main body on which a front side is open, and a slit member which is mounted to the front side of the main body and provided with a front slit for extracting ions. An inner surface of the main body which is exposed to the plasma generation space is made of a refractory metal material, and an inner surface of the slit member which is exposed to the plasma generation space is made of graphite.

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.

An ion implantation system is provided having an ion source configured to form an ion beam from aluminum iodide. A beamline assembly selectively transports the ion beam to an end station configured to accept the ion beam for implantation of aluminum ions into a workpiece. The ion source has a solid-state material source having aluminum iodide in a solid form. A solid source vaporizer vaporizes the aluminum iodide, defining gaseous aluminum iodide. An arc chamber forms a plasma from the gaseous aluminum iodide, where arc current from a power supply is configured to dissociate aluminum ions from the aluminum iodide. One or more extraction electrodes extract the ion beam from the arc chamber. A water vapor source further introduces water to react residual aluminum iodide to form hydroiodic acid, where the residual aluminum iodide and hydroiodic acid is evacuated from the system.

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 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 a first thickness, ranging between 1 mm to 5 mm.

Provided herein are approaches for reducing particles in an ion implanter. An electrostatic filter may include a housing and a plurality of conductive beam optics within the housing. The conductive beam optics are arranged around an ion beam-line directed towards a wafer, and may include entrance aperture electrodes proximate an entrance aperture of the housing. The conductive beam optics may further include energetic electrodes downstream along the ion beam-line from the entrance aperture electrodes, and ground electrodes downstream from the energetic electrodes. The energetic electrodes are positioned farther away from the ion beam-line than the entrance electrodes and the ground electrodes, thus causing the energetic electrodes to be physically blocked from impact by an envelope of back-sputter material returning from the wafer. The electrostatic filter may further include an electrical system for independently delivering a voltage and a current to each of the conductive beam optics.

A collecting plate is disclosed. The collecting plate includes a body having a plurality of holes arranged in an array and a plurality of mitt members respectively disposed over the plurality of holes. The holes and the mitt members are configured to capture and store contaminant particle and prevent contaminant particles from entering processing chamber.

The invention provided an ion implantation system. The ion implantation system comprises an ion emitting device and a target plate device; the target plate device comprises a graphite electrode unit and a power supply unit; the graphite electrode unit is mounted on the lower end of a support frame, and the graphite electrode unit is a hollow structure; the graphite electrode unit comprises a graphite electrode and a hollow region I, the graphite electrode is connected to the power supply unit; the area of the hollow region I is smaller than that of the wafer to be processed, and the sum of the area of the graphite electrode and the area of the hollow region I is larger than an implantation area of the ion beam. When the ion beam is implanted to the wafer to be processed on a target plate for ion implantation, the power supply unit applies a voltage to the graphite electrode to generate an electric field in the opposite direction from the electric field generated by the ion beam motion, accordingly, the speed of the ion beam implanted to a location outside the wafer to be processed is reduced, and secondary contamination during ion implantation is avoided, so as to perform an ion implantation process more efficiently.

An ion implantation system is provided having an ion source configured to form an ion beam from aluminum iodide. A beamline assembly selectively transports the ion beam to an end station configured to accept the ion beam for implantation of aluminum ions into a workpiece. An arc chamber forms a plasma from the aluminum iodide, where arc current from a power supply is configured to dissociate aluminum ions from the aluminum iodide. One or more extraction electrodes extract the ion beam from the arc chamber. A hydrogen co-gas source further introduces a hydrogen co-gas to react residual aluminum iodide and iodide, where the reacted residual aluminum iodide and iodide is evacuated from the system.

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.