A system and method for fueling a fusion reactor. The system includes a reactor chamber containing a stable plasma including a fusion fuel; a heating system configured to heat the plasma and increase an ion energy of the plasma to a level sufficient for producing net power from fusion reactions in the stable plasma; a plurality of magnets coaxial to the reactor chamber, the plurality of magnets producing a magnetic field sufficient to confine the stable plasma and promote rapid loss of fusion products into a scrape off layer; and a neutral beam injection system configured to inject additional quantities of the fusion fuel to sustain the power output of the fusion reaction.

A system and method for fueling a fusion reactor. The system includes a reactor chamber containing a stable plasma including a fusion fuel; a heating system configured to heat the plasma and increase an ion energy of the plasma to a level sufficient for producing net power from fusion reactions in the stable plasma; a plurality of magnets coaxial to the reactor chamber, the plurality of magnets producing a magnetic field sufficient to confine the stable plasma and promote rapid loss of fusion products into a scrape off layer; and a neutral beam injection system configured to inject additional quantities of the fusion fuel to sustain the power output of the fusion reaction.

A non-resonance photo-neutralizer for negative ion-based neutral beam injectors. The non-resonance photo-neutralizer utilizes a nonresonant photon accumulation, wherein the path of a photon becomes tangled and trapped in a certain space region, i.e., the photon trap. The trap is preferably formed by two smooth mirror surfaces facing each other with at least one of the mirrors being concave. In its simplest form, the trap is elliptical. A confinement region is a region near a family of normals, which are common to both mirror surfaces. The photons with a sufficiently small angle of deviation from the nearest common normal are confined. Depending on specific conditions, the shape of the mirror surface may be one of spherical, elliptical, cylindrical, or toroidal geometry, or a combination thereof.

A non-resonance photo-neutralizer for negative ion-based neutral beam injectors. The non-resonance photo-neutralizer utilizes a nonresonant photon accumulation, wherein the path of a photon becomes tangled and trapped in a certain space region, i.e., the photon trap. The trap is preferably formed by two smooth mirror surfaces facing each other with at least one of the mirrors being concave. In its simplest form, the trap is elliptical. A confinement region is a region near a family of normals, which are common to both mirror surfaces. The photons with a sufficiently small angle of deviation from the nearest common normal are confined. Depending on specific conditions, the shape of the mirror surface may be one of spherical, elliptical, cylindrical, or toroidal geometry, or a combination thereof.

An extreme UV light generation device may include: a chamber having a plasma generation region at an inside of the chamber, the chamber receiving a target substance externally supplied to the plasma generation region; an outlet port provided on the chamber; a magnetic field generating unit configured to generate a magnetic field to converge cations on the outlet port, the cations being generated from the target substance that has been turned into plasma in the plasma generation region; an electron emission unit configured to emit electrons neutralizing the cations; and an exhaust tube joined to the outlet port and through which a neutralized substance obtained by neutralizing the cations flows.

An extreme UV light generation device may include: a chamber having a plasma generation region at an inside of the chamber, the chamber receiving a target substance externally supplied to the plasma generation region; an outlet port provided on the chamber; a magnetic field generating unit configured to generate a magnetic field to converge cations on the outlet port, the cations being generated from the target substance that has been turned into plasma in the plasma generation region; an electron emission unit configured to emit electrons neutralizing the cations; and an exhaust tube joined to the outlet port and through which a neutralized substance obtained by neutralizing the cations flows.

A system for reducing surface and embedded charge in a substrate includes a substrate support configured to support a substrate. A vacuum ultraviolet (VUV) assembly is arranged adjacent to the substrate and includes a housing and a VUV lamp that is connected to the housing and that generates and directs ultraviolet (UV) light at the substrate. A movement device is configured to move at least one of the VUV assembly and the substrate support during exposure of the substrate to the UV light to reduce surface and embedded charge in the substrate.

A system for reducing surface and embedded charge in a substrate includes a substrate support configured to support a substrate. A vacuum ultraviolet (VUV) assembly is arranged adjacent to the substrate and includes a housing and a VUV lamp that is connected to the housing and that generates and directs ultraviolet (UV) light at the substrate. A movement device is configured to move at least one of the VUV assembly and the substrate support during exposure of the substrate to the UV light to reduce surface and embedded charge in the substrate.

The invention relates to a method and apparatus for determining actual points along a positively charged particle beam path and/or vectors of the charged particle beam path, where the determined points and vectors aid tomographic construction of a three-dimensional image of a tumor and surrounding tissue. Further, the determined points and vectors of the positively charged particle beam are used in beam control safety, to modify a tumor treatment plan in real time, and/or in combination with co-gathered X-ray images to form a hybrid proton tomographyX-ray three-dimensional image. Preferably, common elements, such as an injector, accelerator, beam transport system, and/or patient positioning system are used for both tumor treatment and tumor imaging.

A negative ion-based beam injector comprising a negative ion source and an accelerator. The ions produced by the ion source are pre-accelerated before injection into a high energy accelerator by an electrostatic multi-aperture grid pre-accelerator, which is used to extract ion beams from the plasma and accelerate to some fraction of the required beam energy. The beam from the ion source passes through a pair of deflecting magnets, which enable the beam to shift off axis before entering the high energy accelerator. The negative ion-based beam injector can be combined with a neutralizer to produce about a 5 MW neutral beam with energy of about 0.50 to 1.0 MeV. After acceleration to full energy, the beam enters the neutralizer where it is partially converted into a neutral beam. The remaining ion species are separated by a magnet and directed into electrostatic energy converters. The neutral beam passes through a gate valve and enters a plasma chamber.