An apparatus for generating high frequency electromagnetic radiation includes a whispering gallery mode resonator, coupled to an output waveguide through a coupling aperture. The resonator has a guiding surface, and supports a whispering gallery electromagnetic eigenmode. An electron source is configured to generate a velocity vector-modulated electron beam, where each electron in the velocity vector-modulated electron beam travels substantially perpendicular to the guiding surface, while interacting with the whispering gallery electromagnetic eigenmode in the whispering gallery mode resonator, generating high frequency electromagnetic radiation in the output waveguide.

A linac-based X-ray system for cargo scanning and imaging applications uses linac design, RF power control, beam current control, and beam current pulse duration control to provide stable sequences of pulses having different energy levels or different doses.

A hybrid linear accelerator is disclosed comprising a standing wave linear accelerator section (“SW section”) followed by a travelling wave linear accelerator section (“TW section”). In one example, RF power is provided to the TW section and power not used by the TW section is provided to the SW section via a waveguide. An RF switch, an RF phase adjuster, and/or an RF power adjuster is provided along the waveguide to change the energy and/or phase of the RF power provided to the SW section. In another example, RF power is provided to both the SW section and the TW section, and RF power not used by the TW section is provided to the SW section, via an RF switch, an RF phase adjuster, and/or an RF power. In another example, an RF load is matched to the output of the TW section by an RF switch.

A hybrid linear accelerator is disclosed comprising a standing wave linear accelerator section (“SW section”) followed by a travelling wave linear accelerator section (“TW section”). In one example, RF power is provided to the TW section and power not used by the TW section is provided to the SW section via a waveguide. An RF switch, an RF phase adjuster, and/or an RF power adjuster is provided along the waveguide to change the energy and/or phase of the RF power provided to the SW section. In another example, RF power is provided to both the SW section and the TW section, and RF power not used by the TW section is provided to the SW section, via an RF switch, an RF phase adjuster, and/or an RF power. In another example, an RF load is matched to the output of the TW section by an RF switch.

Disclosed herein is a waveguide for use in a linear accelerator. The waveguide comprises cells arranged to receive a beam of charged particles therethrough along a particle path, and is configured to receive an electromagnetic field from a source of electromagnetic radiation. A plurality of the cells are individually switchable cells, with each individually switchable cell comprising a respective switch configured to adjust the supply of electromagnetic radiation to the individually switchable cell.

Disclosed herein is a waveguide for use in a linear accelerator. The waveguide comprises cells arranged to receive a beam of charged particles therethrough along a particle path, and is configured to receive an electromagnetic field from a source of electromagnetic radiation. A plurality of the cells are individually switchable cells, with each individually switchable cell comprising a respective switch configured to adjust the supply of electromagnetic radiation to the individually switchable cell.

Embodiments herein are directed to a linear accelerator assembly for an ion implanter. In some embodiments, the linear accelerator assembly may include a central support within a chamber, and a plurality of modules coupled to the central support, at least one module of the plurality of modules including an electrode having an aperture for receiving and delivering an ion beam along a beamline axis.

An apparatus may include a drift tube assembly, arranged to transmit an ion beam. The drift tube assembly may include a first ground electrode; an RF drift tube assembly, disposed downstream of the first ground electrode; and a second ground electrode, disposed downstream of the RF drift tube assembly. The RF drift tube assembly may define a triple gap configuration. The apparatus may include a resonator, where the resonator comprises a toroidal coil, having a first end, connected to a first RF drift tube of the RF drift tube assembly, and a second end, connected to a second RF drift tube of the RF drift tube assembly.

An apparatus may include a drift tube assembly, arranged to transmit an ion beam. The drift tube assembly may include a first ground electrode; an RF drift tube assembly, disposed downstream of the first ground electrode; and a second ground electrode, disposed downstream of the RF drift tube assembly. The RF drift tube assembly may define a triple gap configuration. The apparatus may include a resonator, where the resonator comprises a toroidal coil, having a first end, connected to a first RF drift tube of the RF drift tube assembly, and a second end, connected to a second RF drift tube of the RF drift tube assembly.

One or more example embodiments of the present invention relates to a radiofrequency source for a linear accelerator system, to the linear accelerator system, to a method for operating a radiofrequency source, and to an associated computer program product.