The invention comprises a method and apparatus for treating a tumor of a patient with positively charged particles, comprising the steps of transporting the positively charged particles along a beam transport path passing sequentially from an accelerator, through a beam transport line, through a nozzle, and toward a position of the patient, the step of transporting further comprising the steps of: (1) terminating a first Bragg peak, of a first set of the positively charged particles, in a position of the tumor and (2) flash treating the tumor with a second Bragg peak, of a second set of the positively charged particles, the second Bragg peak terminating post-patient relative to the nozzle. Optionally the second set of particles are delivered at a rate exceeding one MHz. Optionally, particles in common are used to both treat the tumor and image the tumor.

The invention comprises a method and apparatus for treating a tumor of a patient with positively charged particles, comprising the steps of transporting the positively charged particles along a beam transport path passing sequentially from an accelerator, through a beam transport line, through a nozzle, and toward a position of the patient, the step of transporting further comprising the steps of: (1) terminating a first Bragg peak, of a first set of the positively charged particles, in a position of the tumor and (2) flash treating the tumor with a second Bragg peak, of a second set of the positively charged particles, the second Bragg peak terminating post-patient relative to the nozzle. Optionally the second set of particles are delivered at a rate exceeding one MHz. Optionally, particles in common are used to both treat the tumor and image the tumor.

The invention comprises a method and apparatus for aligning a charged particle beam path for treating a tumor of a patient, comprising: a cancer therapy system comprising the charged particle beam path sequentially passing: from an injector, through a synchrotron, along a beam transport line, and through a nozzle; a first two-dimensional detector configured to measure a beam state of positively charged particles; and an integrated intelligent system configured to classify the beam state into a set of beam shape factors, the integrated intelligent system configured to correct the beam shape through application of a condition-action rule: (1) adjusting a first voltage delivered to a first magnet positioned in the beam line prior to the first two-dimensional detector and (2) altering the beam shape through application of a second voltage to a second magnet position in the beam line adjacent to the first magnet.

The invention comprises a method and apparatus for aligning a charged particle beam path for treating a tumor of a patient, comprising: a cancer therapy system comprising the charged particle beam path sequentially passing: from an injector, through a synchrotron, along a beam transport line, and through a nozzle; a first two-dimensional detector configured to measure a beam state of positively charged particles; and an integrated intelligent system configured to classify the beam state into a set of beam shape factors, the integrated intelligent system configured to correct the beam shape through application of a condition-action rule: (1) adjusting a first voltage delivered to a first magnet positioned in the beam line prior to the first two-dimensional detector and (2) altering the beam shape through application of a second voltage to a second magnet position in the beam line adjacent to the first magnet.

A technique for outputting heterologous ions having the same per-nucleon energy at different timings by using one ion source is provided.

An ion generation device includes: an ion generation energy setter that causes first ions and second ions generated by ionization in a vacuum chamber to be emitted in a mixed state from an opening; an electric-field voltage adjuster that imparts a same predetermined per-nucleon energy to each of the first and second ions by applying electric potential formed between the opening and extraction electrodes while switching the electric potential between first and second electric-field voltages; and an excitation current adjuster that causes the first and second ions to be outputted at different timings by supplying a coil of a separation electromagnet with an excitation current while switching the excitation current between first and second excitation currents.

A radioisotope production apparatus comprising an electron source arranged to provide an electron beam. The electron source comprises an electron injector and an electron accelerator. The radioisotope production apparatus further comprises a target support structure configured to hold a target and a beam splitter arranged to direct the a first portion of the electron beam along a first path towards a first side of the target and to direct a second portion of the electron beam along a second path towards a second side of the target.

The invention comprises a method and apparatus for treating a tumor of a patient with positively charged particles, comprising the steps of: (1) transporting the positively charged particles sequentially from an accelerator, through a beam transport line, through a nozzle, and toward a position of the tumor; (2) treating the tumor with first particles, of the positively charged particles, where at least fifty percent of the first particles pass through a patient position, from the nozzle, to a post-patient position; and (3) detecting a beam position of the first particles in the post-patient position with a detector. The flash treatment preferably delivers the first particles at a rate exceeding one MHz.

The invention comprises a method and apparatus for treating a tumor of a patient with positively charged particles, comprising the steps of: (1) transporting the positively charged particles sequentially from an accelerator, through a beam transport line, through a nozzle, and toward a position of the tumor; (2) treating the tumor with first particles, of the positively charged particles, where at least fifty percent of the first particles pass through a patient position, from the nozzle, to a post-patient position; and (3) detecting a beam position of the first particles in the post-patient position with a detector. The flash treatment preferably delivers the first particles at a rate exceeding one MHz.

The present application discloses a control method for fast trapping and high-frequency mutual ejection of cold atom groups. The control method includes: arranging three groups of optical stops on three groups of light sources (splitters) in three-dimensional magneto-optical traps, to form a shaded regions; ejecting a cold atom group from the first three-dimensional magneto-optical trap along a movement trajectory to the second three-dimensional magneto-optical trap, where the movement trajectory passes through the shaded regions of the two three-dimensional magneto-optical traps; and, when it is determined that the cold atom group enters the shaded region of the first three-dimensional magneto-optical trap, trapping a next cold atom group by turning on three-dimensional cooling light and three-dimensional repumping light in the first three-dimensional magneto-optical trap.

The present application discloses a control method for fast trapping and high-frequency mutual ejection of cold atom groups. The control method includes: arranging three groups of optical stops on three groups of light sources (splitters) in three-dimensional magneto-optical traps, to form a shaded regions; ejecting a cold atom group from the first three-dimensional magneto-optical trap along a movement trajectory to the second three-dimensional magneto-optical trap, where the movement trajectory passes through the shaded regions of the two three-dimensional magneto-optical traps; and, when it is determined that the cold atom group enters the shaded region of the first three-dimensional magneto-optical trap, trapping a next cold atom group by turning on three-dimensional cooling light and three-dimensional repumping light in the first three-dimensional magneto-optical trap.