Provided is an ion beam treatment apparatus. The ion beam treatment apparatus includes a laser generation unit, a dividing part dividing a pulse laser beam generated in the laser generation unit into a first laser beam and a second laser beam, a first target part receiving the first laser beam from the dividing part to generate a first ion beam, a second target part receiving the second laser beam from the dividing part to generate a second ion beam, a first path adjusting part adjusting a path of the first ion beam to irradiate the first ion beam to a treated patient, and a second path adjusting part adjusting a path of the second ion beam to irradiate the second ion beam to the treated patient.

The invention comprises a method and apparatus for imaging a tumor of a patient using one or more imaging systems positionable about the tumor and treating the tumor using positively charged particles, such as: (1) using a rotatable gantry support to support and rotate a section of a positively charged particle beam transport line about a rotation axis and a tumor of a patient; (2) using a rotatable and optionally extendable secondary support to support, circumferentially position, and laterally position a primary and optional secondary imaging system about the tumor; (3) image the tumor using the primary and optional secondary imaging system as a function of rotation and/or translation of the secondary support; and (4) treat, optionally concurrently with imaging, the tumor using the positively charged particles as a function of circumferential position of the section of the charged particle beam about the tumor.

A plasmon generator comprises a plasmon supporting surface and first and second quantum systems respectively defining first and second quantum states with a tunneling junction being present between the first and second quantum systems, the first and second quantum systems being present in an electric circuit to generate a tunneling current between the first and second quantum systems, whereby electrons tunneling between said first and second quantum states loose energy in the process and generate plasmons at the plasmon supporting surface.

A plasmon generator comprises a plasmon supporting surface and first and second quantum systems respectively defining first and second quantum states with a tunneling junction being present between the first and second quantum systems, the first and second quantum systems being present in an electric circuit to generate a tunneling current between the first and second quantum systems, whereby electrons tunneling between said first and second quantum states loose energy in the process and generate plasmons at the plasmon supporting surface.

The invention comprises an apparatus and method of use thereof for extracting ions from an ion source, such as for use in cancer treatment or tomographic imaging. The extraction apparatus uses a triode extraction system, with the ion source and/or first electrode held at a first potential; an extraction electrode held at a second potential; and a gating electrode, positioned between the ion source and the extraction electrode, oscillating and/or alternating between a first suppression potential proximate that of the ion source potential and a second extraction potential between the ion source potential and the extraction electrode potential. Optionally, the ion source comprises an electron cyclotron resonance ion source.

The invention comprises an apparatus and method of use thereof for extracting ions from an ion source, such as for use in cancer treatment or tomographic imaging. The extraction apparatus uses a triode extraction system, with the ion source and/or first electrode held at a first potential; an extraction electrode held at a second potential; and a gating electrode, positioned between the ion source and the extraction electrode, oscillating and/or alternating between a first suppression potential proximate that of the ion source potential and a second extraction potential between the ion source potential and the extraction electrode potential. Optionally, the ion source comprises an electron cyclotron resonance ion source.

The X-ray phase imaging apparatus includes a position switching mechanism for switching a relative position of one or more gratings between a retreated position which is an outside of a detection range on a detection surface of an image signal detector and a detection positon which is an inside of the detection range on the detection surface of the image signal detector and a focal diameter changing unit configured to change a focal diameter of the X-ray source in conjunction with switching of the relative position of the one or more gratings.

A method for controlling a density distribution of electrons provided by an electron source for use in hard X-ray, soft X-ray and/or extreme ultraviolet generation, the method comprising generating a plurality of electrons from a pattern of ultracold excited atoms using an ionization laser inside a cavity, wherein the electrons have a density distribution determined by at least one of the patterns of excited atoms and the ionization laser, and accelerating the electrons out of the cavity using a non-static acceleration profile, wherein the acceleration profile controls the density distribution of the electrons as they exit the cavity.

The invention comprises a positively charged particle based cancer therapy system integrated with at least one off-axis imaging system, where elements of the off-axis imaging system and the cancer therapy system are co-positioned/co-rotated with a gantry. The imaging apparatus optionally functions with a tomography system using the positively charged particles of the cancer therapy system for enhanced patient/tumor imaging at and/or prior to a time of treatment.

The invention comprises a positively charged particle based cancer therapy system integrated with at least one off-axis imaging system, where elements of the off-axis imaging system and the cancer therapy system are co-positioned/co-rotated with a gantry. The imaging apparatus optionally functions with a tomography system using the positively charged particles of the cancer therapy system for enhanced patient/tumor imaging at and/or prior to a time of treatment.