A method for producing a radionuclide comprises irradiating a target material with a linear accelerator to produce a radionuclide, dissolving the irradiated target material comprising the radionuclide, and separating the radionuclide from the irradiated target material. Additional methods are disclosed.

A converter for generating photons from an electron beam is provided. The converter may include a plurality of converter plates (i) positioned perpendicular to an axis and (ii) arranged sequentially in a direction along the axis from a first converter plate of the plurality of converter plates to a last converter plate of the plurality of converter plates. The first converter plate may be configured to receive an electron beam traveling in the direction along the axis. Further, the first converter plate may have a thickness smaller than a thickness of the last converter plate, wherein a thickness of a particular converter plate is measured along the axis.

A method for constructing a photon source model function of a medical linear accelerator, for calculating the dose of rays in a radiation therapy scheme is disclosed. A source model of a therapeutic photon beam of the accelerator includes a primary ray photon source model and a scattered ray photon source model. Physical parameters in the two parts of source model functions include the position coordinates of an emission point of a particle, a projection value of a unit momentum vector in a three-dimensional orthogonal direction, and the energy of the particle. By utilizing the model functions, photon fluence information, energy spectrum information, and unit momentum direction information of photons on any phase space plane can be accurately calculated. The method and thought for constructing the source model are applicable to construction of source models of photon beams with various nominal energies of the accelerator used in a radiation therapy.

The embodiments of the present disclosure provide a method for producing Ac-225 from Ra-226, comprising submitting Ra-226 to a photo-nuclear process, collecting an electrochemical precipitation of an Ac-225 on a cathode in a recipient, removing the cathode from the recipient after the electrochemical precipitation of the Ac-225, transferring the cathode to a hot cell environment, and extracting the Ac-225 from the cathode in the hot cell environment. The Ra-226 may comprise a liquid solution in the recipient, and submitting Ra-226 to the photo-nuclear process may comprise irradiating the Ra-226 to produce Ra-225. The Ra-225 may decay into Ac-225 upon irradiation of the Ra-226.

The embodiments of the present disclosure provide a method for producing Ac-225 from Ra-226, comprising submitting Ra-226 to a photo-nuclear process, collecting an electrochemical precipitation of an Ac-225 on a cathode in a recipient, removing the cathode from the recipient after the electrochemical precipitation of the Ac-225, transferring the cathode to a hot cell environment, and extracting the Ac-225 from the cathode in the hot cell environment. The Ra-226 may comprise a liquid solution in the recipient, and submitting Ra-226 to the photo-nuclear process may comprise irradiating the Ra-226 to produce Ra-225. The Ra-225 may decay into Ac-225 upon irradiation of the Ra-226.

An apparatus including a heating element and a sublimation vessel disposed adjacent the heating element such that the heating element heats a portion thereof. A collection vessel is removably disposed within the sublimation vessel and is open on an end thereof. A crucible is configured to sealingly position a solid mixture against the collection vessel.

An apparatus including a heating element and a sublimation vessel disposed adjacent the heating element such that the heating element heats a portion thereof. A collection vessel is removably disposed within the sublimation vessel and is open on an end thereof. A crucible is configured to sealingly position a solid mixture against the collection vessel.

A radioisotope generator including a laser, a volume of target isotope, and nanoparticles in a solid, liquid, or gas state is provided. In at least one aspect, the radioisotope generator accelerates the decay rate of an isotope, with the laser being used to accelerate the decay of the isotope for the production of desired product isotopes.

A radioisotope generator including a laser, a volume of target isotope, and nanoparticles in a solid, liquid, or gas state is provided. In at least one aspect, the radioisotope generator accelerates the decay rate of an isotope, with the laser being used to accelerate the decay of the isotope for the production of desired product isotopes.

One embodiment of the present invention relates to a production method of .sup.225Ac includes; a production step of a .sup.226Ra target including an electrodeposition step of electrodepositing a .sup.226Ra-containing substance on a substrate by using an electrodeposition solution that contains .sup.226Ra ions and a pH buffer, and an irradiating step of irradiating the .sup.226Ra target with at least one selected from charged particles, photons, and neutrons.