An ion implanter. The ion implanter may include an ion source to generate an ion beam; and a linear accelerator, to transport and accelerate the ion beam, the linear accelerator comprising a plurality of acceleration stages. A given acceleration stage of the plurality of acceleration stages may include an RF power supply, arranged to output an RF signal, and a drift tube assembly, arranged to transmit the ion beam, and coupled to the RF power supply. The given stage may also include a resonator, the resonator comprising a resonator enclosure, having a tapered shape, wherein the resonator enclosure has a first width in a middle location, a second width at a first end and a third width at a second end, wherein the first width is greater than the second width and greater than the third width.

An accelerating cavity includes: a housing that is conductive, has a tubular shape, and is formed by joining a plurality of part members parted by a planar parting surface along a central axis; a plurality of cells that are arranged in the housing along an axial direction of the central axis of the housing, and are connected to each other by a communicating portion that allows charged particles to pass through; and a protrusion that is disposed at a position surrounding the communicating portion of each of the cells in the housing, protrudes toward an inner side of the cell in the axial direction, and has a shape becoming larger in a radial direction with respect to the central axis from a tip end portion toward a base end portion in the axial direction.

An ion implanter, including an ion source and extraction system, arranged to generate an ion beam at a first ion energy, and a linear accelerator, arranged to accelerate the ion beam to a second ion energy, wherein the linear accelerator comprises a plurality of acceleration stages coupled to receive a plurality of RF signals from a plurality of power assemblies, respectively. The linear accelerator may be configured wherein at least one stage of the plurality of acceleration stages is coupled to: reversibly connect to a first power assembly, comprising a resonator that contains a resonator enclosure, the first power assembly generating a first RF signal at a first frequency; to disconnect from the first power assembly; and to connect to a second power assembly, generating a second RF signal at a second frequency, greater than the first frequency, while not changing the resonator enclosure.

A power feedthrough assembly for a linear accelerator. The power feedthrough assembly may include an insulating housing, comprising a curved ceramic shell, and a conductive rod, coupled to deliver an RF voltage to a given acceleration stage of the linear accelerator, where the conductive rod extends through an aperture in the insulating housing. The power feedthrough assembly may also include a flange, coupled to mechanically connect the insulating housing to a wall of the linear accelerator. As such, the insulating housing may include a coupling structure that couples the insulating housing to the conductive rod and to the flange, wherein the coupling structure comprises at least one protrusion configured to couple with an external structure that is located in the flange or the conductive rod.

An ion implanter, including an ion source and extraction system, arranged to generate an ion beam at a first ion energy, and a linear accelerator, arranged to accelerate the ion beam to a second ion energy, wherein the linear accelerator comprises a plurality of acceleration stages coupled to receive a plurality of RF signals from a plurality of power assemblies, respectively. The linear accelerator may be configured wherein at least one stage of the plurality of acceleration stages is coupled to: reversibly connect to a first power assembly, comprising a resonator that contains a resonator enclosure, the first power assembly generating a first RF signal at a first frequency; to disconnect from the first power assembly; and to connect to a second power assembly, generating a second RF signal at a second frequency, greater than the first frequency, while not changing the resonator enclosure.