Embodiments herein are directed to a linear accelerator assembly for an ion implanter, wherein the linear accelerator includes a jacketed resonator coil. In some embodiments, a linear accelerator assembly may include a first fluid conduit and a coil resonator coupled to the first fluid conduit, wherein the coil resonator is operable to receive a first fluid via the first fluid conduit, wherein the coil resonator comprises a first coil conduit adjacent a second coil conduit, and wherein a first fluid channel defined by the first coil conduit is operable to receive the first fluid.

Embodiments herein are directed to a linear accelerator assembly for an ion implanter, wherein the linear accelerator includes a jacketed resonator coil. In some embodiments, a linear accelerator assembly may include a first fluid conduit and a coil resonator coupled to the first fluid conduit, wherein the coil resonator is operable to receive a first fluid via the first fluid conduit, wherein the coil resonator comprises a first coil conduit adjacent a second coil conduit, and wherein a first fluid channel defined by the first coil conduit is operable to receive the first fluid.

An exciter for a high frequency resonator. The exciter may include an exciter coil inner portion, extending along an exciter axis, an exciter coil loop, disposed at a distal end of the exciter coil inner portion. The exciter may also include a drive mechanism, including at least a rotation component to rotate the exciter coil loop around the exciter axis.

Embodiments herein are directed to a linear accelerator assembly for an ion implanter. In some embodiments, a LINAC may include a coil resonator and a plurality of drift tubes coupled to the coil resonator by a set of flexible leads.

Embodiments herein are directed to a linear accelerator assembly for an ion implanter. In some embodiments, a LINAC may include a coil resonator and a plurality of drift tubes coupled to the coil resonator by a set of flexible leads.

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.

A method of generating power using a Thorium-containing molten salt fuel is disclosed. One example includes the steps of providing a vessel containing a molten salt fuel, generating a proton beam externally to the vessel, where the externally generated proton beam is of an energy level sufficient to interact with material within a fuel rod in the vessel to produce (p, n) reactions resulting in the generation of neutrons at a first energy level. Neutrons generated within the vessel through the (p, n) reactions are utilized to produce a fission reaction which increases the heat content of the molten salt within the vessel. In the example, a heat exchanger is used to extract heat from the molten salt within the vessel and power is generated from the extracted heat.

An over-voltage protection system for an accelerator can include: a plurality of DC power supplies configured to provide a plurality of voltage levels up to a desired voltage level; and an acceleration tube electrically connected to the plurality of DC power supplies and configured to accelerate a charged particle. The acceleration tube can include a plurality of stages. Each stage can include a plurality of electrodes and a plurality of varistors configured to discharge energy in response to an overvoltage event. One electrode of the plurality of electrodes can be electrically coupled to a voltage level of the plurality of voltage levels. The plurality of electrodes and the plurality of varistors can be electrically coupled to each other and arranged in an alternating fashion.

A mass analyzer includes a main substrate, an upper substrate adhered to the main substrate, and a lower substrate. A mass analysis room (cavity) is formed in the main substrate and penetrates from an upper surface of the first main substrate to a lower surface of the first main substrate. A vertical direction (Z direction) to the main substrate by the upper substrate, both sides of the lower substrate, a travelling direction (X direction) of charged particles and a right angle to the Z direction by the main substrate, and both sides of a right-angled direction (Y to Z direction) and the X direction by a side surface of the main substrate are surrounded. A central hole is open in the side plate of the main substrate that the charged particles enter. The charged particles enter the mass analysis room through the central hole formed in the first main substrate.

Provided herein are high energy ion beam generator systems and methods that provide low cost, high performance, robust, consistent, uniform, low gas consumption and high current/high-moderate voltage generation of neutrons and protons. Such systems and methods find use for the commercial-scale generation of neutrons and protons for a wide variety of research, medical, security, and industrial processes.