A first system for producing a high flux of neutrons for non-destructive testing includes a dense plasma focus device neutronically coupled to a subcritical or sub-prompt critical fission assembly. The dense plasma focus device is a source of initiating neutrons for the fission assembly, and the fission assembly is configured to multiply a number of the initiating neutrons via inducing fission. A second system for producing a high flux of neutrons includes a gas-target neutron generator neutronically coupled to a subcritical or sub-prompt critical fission assembly. The gas-target neutron generator is a source of initiating neutrons for the fission assembly, and the fission assembly is configured to multiply a number of the initiating neutrons via inducing fission.

A first system for producing a high flux of neutrons for non-destructive testing includes a dense plasma focus device neutronically coupled to a subcritical or sub-prompt critical fission assembly. The dense plasma focus device is a source of initiating neutrons for the fission assembly, and the fission assembly is configured to multiply a number of the initiating neutrons via inducing fission. A second system for producing a high flux of neutrons includes a gas-target neutron generator neutronically coupled to a subcritical or sub-prompt critical fission assembly. The gas-target neutron generator is a source of initiating neutrons for the fission assembly, and the fission assembly is configured to multiply a number of the initiating neutrons via inducing fission.

The invention provides a device for the production, moderation and configuration of a neutron beam, comprising: an inlet opening (1) through which a proton beam is directed; a target (2) against which the proton beam is accelerated in order to generate neutrons; a moderator (3) to bring the neutrons to energies of the epithermal range; a reflective cover (4) surrounding the moderator (3); a filtration stage (5); an outlet opening (6) for the neutron beam, and a shield (7) to suppress the neutrons and gamma-radiation that do not exit the device via said outlet opening. The filtration stage (5) comprises at least three layers to filter respectively: rapid neutrons, thermal neutrons and gamma-radiation The invention is of use in neutron capture therapies, and more specifically, in boron therapies.

The invention provides a device for the production, moderation and configuration of a neutron beam, comprising: an inlet opening (1) through which a proton beam is directed; a target (2) against which the proton beam is accelerated in order to generate neutrons; a moderator (3) to bring the neutrons to energies of the epithermal range; a reflective cover (4) surrounding the moderator (3); a filtration stage (5); an outlet opening (6) for the neutron beam, and a shield (7) to suppress the neutrons and gamma-radiation that do not exit the device via said outlet opening. The filtration stage (5) comprises at least three layers to filter respectively: rapid neutrons, thermal neutrons and gamma-radiation The invention is of use in neutron capture therapies, and more specifically, in boron therapies.

A novel thin-film target can the life of tritium targets for the production of 14 MeV neutrons by the .sup.3H(.sup.2H,n).sup.4He nuclear reaction while using only a small fraction of the amount of tritium compared to a standard thick-film target. With the thin-film target, the incident deuterium is implanted through the front tritide film into the underlying substrate material. A thin permeation barrier layer between the tritide film and substrate reduces the rate of tritium loss from the tritide film. As an example, good thin-film target performance was achieved using W and Fe for the barrier and substrate materials, respectively.

Provided is a radiation detection system for improving the accuracy of a neutron beam irradiation dose for a neutron capture therapy system. The neutron capture therapy system includes a charged particle beam, a charged particle beam inlet for passing the charged particle beam, a neutron generating unit for generating the neutron beam by means of a nuclear reaction with the charged particle beam, a beam shaping assembly for adjusting flux and quality of the neutron beam, and a beam outlet adjoining to the beam shaping assembly, the radiation detection system includes a radiation detection device arranged within the beam shaper or outside the beam shaping assembly, the radiation detection device is used for real-time detection of the overflowing neutron beam by the neutron generating unit or the generated γ-ray after the nuclear reaction of the charged particle beam with the neutron generating unit.

Provided is a radiation detection system for improving the accuracy of a neutron beam irradiation dose for a neutron capture therapy system. The neutron capture therapy system includes a charged particle beam, a charged particle beam inlet for passing the charged particle beam, a neutron generating unit for generating the neutron beam by means of a nuclear reaction with the charged particle beam, a beam shaping assembly for adjusting flux and quality of the neutron beam, and a beam outlet adjoining to the beam shaping assembly, the radiation detection system includes a radiation detection device arranged within the beam shaper or outside the beam shaping assembly, the radiation detection device is used for real-time detection of the overflowing neutron beam by the neutron generating unit or the generated γ-ray after the nuclear reaction of the charged particle beam with the neutron generating unit.

Provided herein are neutron imaging systems (e.g., radiography and tomography) systems and methods that provide, for example, high-quality, high throughput 2D and 3D fast or thermal neutron and/or X-ray images. Such systems and methods find use for the commercial-scale imaging of industrial components. In certain embodiments, provided herein are system comprising a plurality of independent neutron absorber-lined collimators (e.g., 4 or more collimators) extending outwards from a central neutron source assembly.

Provided herein are neutron imaging systems (e.g., radiography and tomography) systems and methods that provide, for example, high-quality, high throughput 2D and 3D fast or thermal neutron and/or X-ray images. Such systems and methods find use for the commercial-scale imaging of industrial components. In certain embodiments, provided herein are system comprising a plurality of independent neutron absorber-lined collimators (e.g., 4 or more collimators) extending outwards from a central neutron source assembly.

Embodiments of systems, devices, and methods relate to controlling beams for use in beam systems. An example method of controlling a travel path of a beam includes propagating a beam along a first path from an entry point of a dipole magnet through a non-gradient portion of the dipole magnet until the beam bends toward a first beam travel path of multiple beam travel paths of the dipole magnet. The example method further includes propagating the beam along the first beam travel path through a gradient portion of the dipole magnet to focus the beam for propagation to a downstream target. Embodiments further permit a compact beam system such that a series of magnets can be used to create a path that accommodates shielding to minimize the footprint of the beam system for facilities that may not otherwise support large systems due to space and safety constraints.