High power converter target assembly, related facility and method to produce bremsstrahlung for photonuclear reactions

1 . A facility for the production of radionuclides, in particular diagnostic and therapeutic radionuclides, based on the principle of photonuclear irradiation, comprising: an electron accelerator, producing an electron beam, a converter target assembly with a converter target that converts the electron beam to Bremsstrahlung photons, a number of production targets, irradiated by the Bremsstrahlung photons and thereby producing said radionuclides, wherein the converter target assembly comprises a sealed housing, the housing enclosing a cavity which holds the converter target, comprising an entry window with a window disk for the electron beam and an exit window for the Bremsstrahlung photons, comprising cooling medium ports, these ports being part of a cooling circuit for establishing a cooling flow through the cavity, thereby cooling the converter target and the window disk, wherein the converter target comprises a number of rotatable converter disks, the electron beam is set off-center with respect to a respective converter disk of the rotatable converter disks, and wherein the respective converter disk is designed to rotate during operation of the facility, thereby, in the course of time, spreading the focal spot of the electron beam over an annular area of the respective converter disk. 2 . The facility according to claim 1 , wherein the electron accelerator generates a pulsed or a continuous wave electron beam, wherein the pulsed or the continuous wave electron beam has impulse times and period times in the range of milliseconds or longer. 3 . The facility according to claim 1 , wherein the electron beam is a pulsed electron beam, and further comprising a control unit which keeps the rotation speed of the respective converter disk synchronized with a time structure of the electron beam pulses. 4 . The facility according to claim 3 , wherein the annular area on the respective converter disk exposed to a single beam pulse describes a complete ring or sectors thereof, wherein the ratio of a revolution time of the respective converter disk to beam pulse time is preferably chosen such that all sectors are irradiated homogeneously over multiple irradiation cycles. 5 . The facility according to claim 1 , wherein a rotation speed of the respective converter disk is set in the range from a few thousands to several ten thousands of revolutions per minute. 6 . The facility according to claim 1 , wherein the window disk is rotatable and held or supported by an entry window holder, the electron beam is set off-center with respect to the window disk, and wherein the window disk is configured to rotate during operation of the facility at a rotation speed, thereby, in the course of time, spreading the focal spot of the electron beam over an annular area of the window disk. 7 . The facility according to claim 6 , wherein the entry window holder comprises or holds a circular window disk, which is a Beryllium foil or high strength material with low atomic number, wherein the entry window holder is coupled to a hollow shaft, which is part of a rotary vacuum feedthrough. 8 . The facility according to claim 7 , wherein the entry window holder and the window disk or the rotary vacuum feedthrough are sealed with respect to a beam transfer line by a magnetofluid sealing. 9 . The facility claim 6 , wherein a control unit keeps the rotation speed of the entry window holder and the mounted window disk synchronized with the time structure of the electron beam pulses. 10 . The facility according to claim 9 , wherein an area on the window disk exposed to a single beam pulse describes a complete ring or sectors thereof, wherein a ratio of the revolution time of the window disk to the beam pulse time is preferably chosen such that all sectors are irradiated homogeneously over multiple irradiation cycles. 11 . The facility claim 6 , wherein the rotation speed of the window disk is set in the range from several hundreds to several thousands of revolutions per minute. 12 . The facility according to claim 1 , wherein a beam transfer line comprises an optical element that allows for focusing or defocusing of the electron beam to different FWHM and, wherein a FWHM of at least 2 mm is set. 13 . The facility according to claim 1 , wherein the converter target comprises four converter disks. 14 . The facility according to claim 13 , wherein the converter disks are stacked on a common shaft. 15 . The facility according to claim 13 , wherein the converter disks are arranged on parallel shafts, such that the converter disks partially overlap when viewed in the direction of the shafts, wherein each shaft is aligned in parallel to the direction of the electron beam. 16 . The facility according to claim 1 , wherein the respective converter disk is coupled to a rotary drive. 17 . The facility according to claim 1 , wherein the converter disk comprise multiple converter disks arranged to form a Tesla pump. 18 . The facility according to claim 1 , wherein the converter disks are configured to be driven by a cooling flow. 19 . The facility according to claim 18 , wherein the converter disks comprise multiple converter disks arranged to form a Tesla turbine. 20 . The facility according to claim 1 , further comprising a cooling medium, wherein the cooling medium is a cooling gas. 21 . The facility according to claim 1 , wherein a region of origin of emerging Bremsstrahlung photons, apart from some optional wobbling with an amplitude in the range of millimeters, is fixed in space. 22 . A converter target assembly for a facility, comprising a sealed housing, the housing enclosing a cavity which holds a converter target, the housing further comprising an entry window holder with a mounted entry window disk for an electron beam and an exit window for Bremsstrahlung photons, the housing further comprising cooling medium ports, the ports being designated to be connected to a cooling circuit for establishing a cooling flow through the cavity, thereby cooling the converter target and the entry window holder with its mounted entry window disk, wherein the converter target comprises a number of rotatable converter disks, and wherein a converter disk of the rotatable converter disks is designed to rotate during operation of the facility, thereby, in the course of time, spreading the focal spot of an incoming electron beam over an annular area of the converter disk. 23 . A converter target assembly according claim 22 , wherein the entry window holder comprises a rotatable window disk, wherein the window disk is configured to rotate during operation of the facility, thereby, in the course of time, spreading the focal spot of an incoming electron beam over an annular area of the window disk. 24 . A method of producing radionuclides, comprising: directing an electron beam onto a converter target with a number of rotating converter disks, such that, in the course of time, a focal spot of the electron beam is spread over an annular area of a converter disk, thereby producing a beam of Bremsstrahlung photons for irradiation of a production target, and cooling the converter target by a flow of cooling medium, wherein the cooling medium is gaseous Helium. 25 . The method of claim 24 , wherein the converter target is arranged inside a housing, and wherein the electron beam is lead through a rotating entry window holder