40th European Cyclotron Progress Meeting

Europe/Rome
Sala Villi (INFN Laboratori Nazionali di Legnaro)

Sala Villi

INFN Laboratori Nazionali di Legnaro

Viale dell'Università 2, Legnaro PD, Italy
Mario Maggiore (LNL)
Description

The European Cyclotron Progress Meeting (ECPM) is devoted to the physics and technology of cyclotrons, their applications in science, medicine and industry, and to related topics. Status reports on existing facilities as well as innovative developments and progress reports on evolving projects will be presented.
Final Information
First Circular
Poster
Second Circular
Participants
  • Alberto Longhitano
  • Alberto Monetti
  • Alessio Galatà
  • Andrea Calore
  • Andrea Denker
  • Antonino Caruso
  • Artur Tiede
  • Augusto Lombardi
  • Brian Jones
  • Carlo De Martinis
  • David Mascali
  • Dmitry Popov
  • Donald May
  • Faisal Alrumayan
  • Gaia Pupillo
  • Galina Asova
  • Galina Karamysheva Karamysheva
  • Gianfranco Prete
  • Gianfranco Vecchio
  • Giuseppe Castro
  • Giuseppe Costa
  • Giuseppe Gallo
  • Grazia D'Agostino
  • Grigori Shirkov
  • Hanna Skliarova
  • Hermann Schweickert
  • Holger Jensen
  • Igor Kalagin
  • Iroshi Inoue
  • Jarno Van de Walle
  • Juan Esposito
  • JUERGEN DUPPICH
  • Karim Butalag
  • Laurent Standaert
  • Leandro Piazza
  • Liliana Mou
  • Lorenzo Pranovi
  • Loris Antoniazzi
  • Luca Silvestrin
  • Lucia Sarchiapone
  • Luciano Calabretta
  • Marc Loiselet
  • Marco Schippers
  • Maria Luisa Allegrini
  • Mario Maggiore
  • Mark Carlson
  • Markus Ehrenfried
  • Matteo Gobbo
  • Maurizio Montis
  • Mauro Giacchini
  • Michele Contran
  • Micòl Pasquali
  • Nancy Postiau
  • Olaf Felden
  • Oleg Karamyshev
  • Omae Kamalou
  • Pasquale Luca De Ruvo
  • Pauli Heikkinen
  • Pedro Calvo Portela
  • Petra Martini
  • Pierfrancesco Mastinu
  • Piergiorgio Antonini
  • Pietro Zanetti
  • Ralf Gebel
  • Richard Johnson
  • Sara Cisternino
  • Saverio Braccini
  • Sergey Bogomolov
  • Stefan Johansson
  • Stefano Frega
  • Sytze Brandenburg
  • Taneli Kalvas
  • Teodor Boiesan
  • Tetsuya Nakanishi
  • Vincent Berghmans
  • Viplav Gupta
  • Vladimir Malinin
  • Vladimir Ryjkov
  • Wiel Kleeven
  • Yi-Nong Rao
  • Yuto Nakashima
    • 17:30
      Registration Caffé Pedrocchi

      Caffé Pedrocchi

    • 18:00
      Welcome Reception Caffé Pedrocchi

      Caffé Pedrocchi

      Via VIII Febbraio, 15 - Padova
    • 07:45
      Bus to LNL Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • 08:30
      Registration Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • 1
      Welcome Address Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
      Speaker: Dr Diego Bettoni (LNL Director)
    • Session 1 Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
      • 2
        The SPES project at the INFN- Laboratori Nazionali di Legnaro
        The SPES project is in the construction phase at the Legnaro National Laboratory (LNL) of INFN. It is an interdisciplinary project, ranging over nuclear physics, nuclear medicine and materials science. SPES will provide a Radioactive Ion Beam facility for the study of neutron rich unstable nuclei of interest to nuclear and astro-nuclear physics research. At the same time, it will host a laboratory for research and production of radioisotopes to be applied in nuclear medicine. SPES is based on a dual exit high current Cyclotron, with proton beam energy 35-70 MeV and 0.2-0.5 mA, used as proton driver to supply an ISOL system with an UCx Direct Target able to sustain a power of 10 kW and produce neutron rich ions at intensities one order of magnitude higher than existing facilities. The second exit will be used for applied physics: radioisotope production for medicine and neutrons for material study. The main SPES physics program is based on the use of the re-accelerated exotic beams by the ALPI superconductive linac which allows having beams at energies in the range of 10 MeV/n. At these energies nuclear reactions with radioactive beams will be possible, and more exotic nuclei by transfer reaction will be produced and studied. The layout of SPES was designed in such a way to operate two targets at the same time distributing the beam according to a schedule that minimizes the radiation problems. The proton beam can be sent to two ISOL target caves, three caves for radioisotopes production and developments and an area for neutron production and material study.
        Speaker: Gianfranco Prete (LNL)
        Slides
      • 3
        Status of High Intensity Beam Facility at LNL
        The High Intensity Beam Facility cyclotron based is under commissioning at LNL. The facility is developing in the SPES project framework and the proton driver will provide a beam up to 50 kW power and 70 MeV energy for research in nuclear physics, medical and neutron source applications as well.
        Speaker: Mario Maggiore (LNL)
        Slides
      • 4
        Upgrading of the LNS Superconducting Cyclotron to deliver beam power higher than 2-5 kW
        The LNS Superconducting Cyclotron has been in operation for more than 20 years. To fulfil the demand of users aiming to study rare processes in Nuclear Physics, the beam power has to be increased up to 210 kW for ions with mass lower than 40 a.m.u.. Extraction by stripping has been envisaged as the best solution for this purpose. To perform the extraction by stripping, a significant refurbishing operation of the Cyclotron is needed, including a new cryostat with new superconducting coils, a new extraction channel with a 60 mm vertical gap, additional penetrations to host new magnetic channels and new compensation bars. A general description of the refurbishing project is presented.
        Speaker: Luciano Calabretta (LNS)
        Slides
    • 10:35
      Coffee-Break Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • Session 2 Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
      • 5
        THE NEW DC-280 CYCLOTRON. STATUS AND PERSPECTIVES
        The status of the project of the DC-280 cyclotron is presented. The DC-280 will be the basic facility of the Super Heavy Element Factory which is being created at the FLNR JINR. The energy of the ions extracted from the cyclotron will be vary from 4 up to 8 MeV/amu. The expected ion beam intensity at DC-280 extraction is 10 pmkA for ions with masses 50-60. The main parts of the DC-280 are already made and are being assembled. In according to FLNR plans the cyclotron has to be assembled in the period from 2016 to 2017. The cyclotron commissioning will be in 2018.
        Speaker: Igor Kalagin (JINR)
        Slides
      • 6
        Status of the HZB cyclotron
        For nearly 20 years, eye tumours are treated in collaboration with the Charité - Universitätsmedizin Berlin. In January 2017 we celebrated the 3000th patient. Parallel to the ongoing tumour therapy, beam time was allocated to experiments. These ranged from radiation hardness testing and nuclear physics over dosimetry to accelerator development. Single pulses of Protons and Helium with different energies have been delivered with repetition rates up to 2 MHz. In order to improve the beam diagnosis between the 2 MV injector Tandetron and the cyclotron a harp has been installed. The first measurements yielded some interesting results, which are not yet fully understood.
        Speaker: Andrea Denker (Helmholtz-Zentrum Berlin)
        Slides
      • 7
        The heavy ion irradiation facility at KVI-CART
        An in-air heavy ion irradiation facility equipped for providing masses up to xenon at 30 MeV/u is being developed at the Kernfysisch Versneller Instituut Center for Advanced Radiation Technology (KVI-CART). KVI-CART has operated a proton irradiation facility for radiobiological research since 1998. Since 2005, this facility has also been used for radiation hardness testing. The K600 superconducting AGOR (Accelerator Groningen Orsay) cyclotron at KVI-CART has been designed to provide ion beams with a large range of charge-to-mass ratios and energies. We are in the process of extending the radiation hardness test capabilities by providing heavy ion beams at several energies ranging from about 8 MeV/u to 90 MeV/u. KVI-CART will provide these irradiations for scientific and commercial users starting in 2018. Three irradiation set-ups are being developed. For irradiations demanding lighter ions, including helium to oxygen at 90 MeV/u, the AGOR FIRM set-up, which was originally developed for protons [1], can be used with minor adaptations. For heavy ion beam irradiations with energies in the range of 8-10 MeV/u, the irradiations must be performed in vacuum using the BIBER irradiation set-up [2], which has been donated to us by HZB Berlin. We are additionally installing a new set-up for irradiations in air with heavy ion beams, specifically for carbon to xenon at 30 MeV/u, that allows for easy access of the device under test. The uniformity, dosimetry, beam purity and switching times of the different ion beams have had an influence on the design considerations of the facility and in particular on the choices of the ions in the beam cocktails. These considerations, as well as new strategies adopted to efficiently operate the sources and cyclotron, will be highlighted. [1] The AGOR Facility for Irradiations of Materials, van der Graaf, E. R., Ostendorf, R. W., van Goethem, M. J., Kiewiet, H. H., Hofstee, M. A. Brandenburg, S. 2010 RADECS 2009 Proceedings. p. 443 [2] BIBER - The Berlin Ion Beam Exposure and Research Facility Optiz-Coutureau, J., Bundesmann, J., Denker, A., & Homeyer, H. Journal: Radiation and its Effects on Components and Systems, RADECS 2003, Proceedings of the 7th European Conference, held 15-19 September 2003 in Noordwijk, The Netherlands. Edited by K. Fletcher. ESA SP-536, ESA/ESTEC, 2004., p.507
        Speaker: Brian Jones (KVI-CART University of Groningen, The Netherlands)
        Slides
      • 8
        STATUS REPORT ON GANIL AND UPGRADE OF SPIRAL1
        The GANIL facility (Grand Accélérateur National d’Ions Lourds) at Caen is dedicated for acceleration of heavy ion beams for nuclear physics, atomic physics, and radiobiology and material irradiation. Nowadays, an intense exotic beam is produced by the Isotope Separation On-Line method at the SPIRAL1 facility since 2001. New demands from the physics community motivated the upgrade of this facility in order to extend the range of post-accelerated radioactive ions. A 2 M€ project allowed the profound modification of the installation and the commissionning has started. The status of the installation and the last results will be presented. The review of the cyclotron operation from 2001 to 2017 will be presented as well.
        Speaker: Omae Kamalou (GANIL)
        Slides
      • 9
        Status of the Texas A&M Radioactive-Beam Project
        The effort at the Texas A&M Cyclotron Institute to produce reaccelerated, radioactive beams is progressing. The K150 cyclotron in combination with ion guides will be used for the production of radioactive ions to be then charge-bred by an electron-cyclotron ion source (ECRIS) for acceleration to intermediate energies by the K500 cyclotron. The methods for tuning and detecting the radioactive beams as well as a new method for direct injection of the low-charge-state radioactive ions into the charge-breeding ECRIS will be presented.
        Speaker: Donald May (Cyclotron Institute, Texas A&M University)
        Slides
    • 13:05
      Lunch Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • 14:30
      Visit to LNL Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • Poster Session Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
      • 17:00
        Coffee-break
    • 18:15
      Bus to Padova Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • 08:15
      Bus to LNL Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • Session 3 Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
      • 10
        Activities from Cyclotrons at German Cancer Research Center (DKFZ), Heidelberg – A Status Report
        The onset of cyclotron history at DKFZ dates back since 1971, when the first compact cyclotron (protons and α-particles: 22MeV; deuterons: 11MeV; 3He: 28MeV) was purchased from Allgemeine Elektrizitäts-Gesellschaft (AEG)-Telefunken, Germany. After its installation at DKFZ, it was employed to produce short lived radionuclides (15O, 18F, 13N, 11C, 81Rb) for the radiochemistry and nuclear medicine. In parallel, an active research program in the field of radiobiology and dosimetry using fast neutrons and light ions was also established. After ca. 17 years of successful operation (1973 - 1990), it was clear that the existing AEG compact cyclotron would not be able to keep up the increasing future demands. Supplies and parts were obsolete, spare parts were nonexistent and operational reliability faded away. Moreover, the applications necessitate higher energies and currents and an application for a higher energy cyclotron was submitted. A second compact cyclotron, and subsequently one of the first available negative ion cyclotrons MC32NI (M = Mini; C = Cyclotron; 32 = 32 MeV proton energy, NI = Negative Ion) from Scanditronix, Uppsala, Sweden, with relatively higher energies (proton: 32MeV; deuterons: 16MeV) was purchased and installed in 1991. Since 1991, the MC32NI cyclotron has had been employed for multiple projects e.g. radionuclides production for clinical (15O, 18F, 13N, 11C, 81Rb) and preclinical (64Cu) applications, nuclear physics experiments, dosimetry, wear measurements of industrial machine parts followed by labeling with 57Co (for ZAG Karlsruhe, Germany) and educational studies. In July 2017 the management board of the DKFZ has decided to shut down the existing cyclotron and replace it with the similar energy cyclotron in another building. The next cyclotron will be employed for clinical applications as well as producing more and more radiometals used in both diagnostic and therapeutic techniques, thereby heading more closely towards appropriate matched-pair combinations – theranostic approach. The existing DKFZ cyclotron facility (≈ 800m2) and its decommissioning, performance and status of the MC32NI cyclotron, different target and beam lines systems, some technical problems occurred in recent times, ongoing radionuclides development, future planned projects, installation of a new cyclotron and bunker systems will be presented in brief.
        Speaker: Viplav Gupta (German Cancer Research Center, Heidelberg)
        Slides
      • 11
        Multi-disciplinary research activities and beam diagnostic detector developments at the Bern medical cyclotron
        The cyclotron laboratory at the Bern University Hospital was conceived for both industrial production of radio-pharmaceuticals and multi-disciplinary research activities. It is based on an IBA CYCLONE 18 MeV proton cyclotron equipped with a 6 m long research beam line accessible by a separate bunker. Studies on accelerator and detector physics, radiation protection, radiation hardness of components for physics experiments and space missions, and novel PET radioisotopes are on-going. The production of radioisotopes via the irradiation of highly enriched materials in form of powders (as enriched calcium for scandium 43 and 44) is challenging and a specific method based on a compact 60 cm long mini beam line equipped with an active beam diagnostic system and a solid target station is being developed. Research on non-destructive beam monitoring detectors is pursued. The UniBEaM is based on doped silica fibers passed through the beam to obtain beam profiles in a large intensity range from 1 pA to 20 uA. Four optical beam profilers of this kind were used to build a specific instrument to measure the transverse beam emittance on-line and to study its behavior as a function of several cyclotron parameters. A two-dimensional non-destructive beam profiler based on a 4 um ultra-thin phosphor screen read out by a CCD camera was conceived and a prototype built. The first results are promising in view of several applications of ion beams such as radioisotope production and hadrontherapy.
        Speaker: Saverio Braccini (University of Bern)
        Slides
      • 12
        Extension of JULICs irradiation capabilities
        At the Forschungszentrum Jülich (FZJ) the variable energy cyclotron JULIC is used as injector of the Cooler Synchrotron (COSY) and performs well for low to medium current irradiations. Main task is to support the FZJ radionuclide research programme of the Institute for Neuroscience and Medicine INM-5 for medical imaging approaches and radioligand development for decoding the complex functions and structure of the human brain (JARA-BRAIN). Target holders of the INM-5 were implemented to the external target station of JULIC to obtain reliable irradiations with 45 MeV protons and 76 MeV deuterons for nuclear reaction cross section measurements and medical radionuclide production. For testing of radiation effects, displacement damage DD and single event effects SEE, with energetic protons for electronics used in space and accelerators the beam can be extracted to a dedicated test stand, e.g. used by Fraunhofer INT. A new external target station is set up inside the BigKarl-Experimental area offering huge space for complex detector setups. This will mainly be used for neutron yield investigations and neutron target development with high power proton or deuteron beam in perspective of a high brilliance accelerator based neutron source (HBS) with the Juelich Center for Neutron Science JCNS-4. In this type of compact neutron sources the neutrons are produced exposing light beryllium targets to proton or deuterium particles of relative low final particle energy in the MeV range and will be optimized for neutron scattering on small samples and to be realized at reasonable costs. But the new target station will be used for other purposes like electronic or detector test and irradiation as well. This report briefly summarizes the history of JULIC and the technical activities for its future perspectives.
        Speaker: Olaf Felden (Forschungszentrum Jülich)
        Slides
      • 13
        Status Update of Cyclotron Laboratory at Institute for Nuclear Research and Nuclear Energy
        The Institute for Nuclear Research and Nuclear Energy is preparing to operate a high-power cyclotron for production of radioisotopes for nuclear medicine, research in radiochemistry, radiobiology, nuclear physics, solid state physics. The cyclotron is a TR24 produced by ASCI, Canada, capable to deliver proton beam in the energy range of 15 to 24 MeV with current as high as 400 uA. Multiple extraction lines can be fed. The primary goal of the project is the production of PET and SPECT isotopes as 18F, 67, 68Ga, 99mTc, etc. This contribution reports the status of the project. Design considerations for the cyclotron vault will be discussed for some of the target radioisotopes. The research has been supported by the Bulgarian Science Fund under Contract No. DN 08/6, 13.12.2016.
        Speaker: Galina Asova (INRNE)
        Slides
    • 10:40
      Coffee-Break Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • Session 4 Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
      • 14
        LARAMED – LAboratory of RAdionuclides for MEDicine: Status of the research facility at INFN LNL
        LARAMED is a new research infrastructure, now under construction at Legnaro National labs (LNL), which will take advantage of the high performance BEST 70p cyclotron (70 MeV, 750 μA ) recently commissioned in the framework of SPES project. LARAMED project is indeed the LNL proposal for an international-class level and well-established research center, which main goals cover different topics, ranging from nuclear physics (excitation function experimental measurements), to engineering aspects (high power production targets) and radiochemistry issues (improvements of separation purification techniques). LARAMED has been conceived, since the beginning, to meet a double research scope: either to develop a more efficient production for well-established radionuclides already playing a key role in nuclear medicine (NM), or to investigate yet unexplored production routes for novel radionuclides, having potential interest for medical applications, but still unavailable in NM. Ultimately, the major objective of this project is to establish a production facility at LNL for a number of relevant medical radionuclides to be distributed to hospitals and clinical departments, both for routine use in patients' treatment and clinical research purposes. The LARAMED infrastructure comprises three dedicated irradiation bunkers, each one having specific beamlines and target stations. One devoted to research purposes, the so-called RadioIsotope LABoratory (RILAB), while the remaining two being available, through settled collaboration agreement with a commercial partner, for routine radionuclides production such as 82Sr/82Rb, 68Ga/68Ge etc., the so-called RadioIsotope FACtory (RIFAC). Both RILAB and RIFAC bunkers will be connected to dedicated radiochemistry laboratories through pneumatic pipelines, designed to transfer irradiated targets into hot cells for separation, purification and handling of the radionuclides of interest. Moreover, a dedicated low-current beam line will be available as well for high-precision determination of nuclear excitation functions. LARAMED was designed according to the following research lines: (1) high-precision determination of nuclear reaction’s cross-sections potentially useful for obtaining novel medical radionuclides, including re-evaluation of previously investigated reaction routes; (2) development of new target technology suitable for operating with high-current, high-energy proton beams, especially for an improved production of 64/67Cu isotopes; (3) development of alternative, more efficient procedures for obtaining important medical radionuclides, including 99mTc, 64/67Cu, 52Mn, 82Sr, 68Ge and 89Zr, 63Zn, 186Re and 44/47Sc; (4) development of fully-automated dedicated radiochemical procedures for target processing, separation and purification of medical radionuclides; (5) design and development of novel radiopharmaceuticals for targeted guided imaging and therapy in oncology.
        Speaker: Juan Esposito (LNL)
      • 15
        Status of NEPIR, the NEutron and Proton Irradiation facility at SPES cyclotron
        At INFN-Legnaro (LNL) there is an ongoing effort to create a suite of neutron sources based on two high current proton accelerators: a 5 MeV (30 mA) linac developed at LNL and the new 35-70 MeV (0.75 mA) cyclotron of SPES. These will produce cold, thermal, epithermal, and fast neutrons for a variety of applied and basic research programs (material characterization, imaging, neutron detectors, nuclear astrophysics, neutron data for MC development, boron neutron capture therapy, radiation damage in electronics...). In particular, the SPES cyclotron will feed NEPIR, an irradiation facility that will deliver both quasi mono-energetic neutron and direct proton beams in the 20-70 MeV energy range for multi-disciplinary applications. A complementary continuous energy atmospheric-like neutron beam for studying neutron-induced Single Event Effects in electronics will also be available. In this contribution, we report on the status of the design and construction plans of NEPIR in view of recent funding.
        Speaker: Luca Silvestrin (PD)
        Slides
      • 16
        The S2C2 : experiences from in-factory testing and on-site installations
        The ProteusONE proton therapy system by IBA, equipped with the superconducting synchro-cyclotron (S2C2) is now operational at 2 proton therapy centers and three more centers are currently being installed. The on-site installations and further in-factory testing of the S2C2 has provided much insight in the reproducibility of the beam characteristics and has showed us a fast and efficient approach to machine commissioning. In this contribution the emphasis will be put on the alignment of the beam out of the S2C2 into the rotating gantry (site experiences), the energy stability and range of the S2C2 and the reproducibility of the beam characteristics. Additionally, the different simulation tools will be presented which enable us to track the beam from the center of the S2C2 up to isocenter. In this way, we can investigate possible perturbations in the ProteusONE system and their impact on the beam performance at the patient level.
        Speaker: Jarno Van de Walle (IBA)
        Slides
      • 17
        Radiometric Survey at the LNL Cyclotron
        The cyclotron recently installed and commissioned at the National Laboratory in Legnaro can deliver proton beams with current up to 700 microA and energy in the range 35-70 MeV. During the machine commissioning, the operational quantities used for radiation protection purposes have been monitored in the installation, both during the beam acceleration/extraction and after the end of irradiation, in order to evaluate prompt and residual radiation. In this work the results of such survey will be shown, compared with numerical simulations used as reference. Measurements of activation of the beam line equipment and of the cooling water will also be shown, together with a discussion on the possible source of contamination.
        Speaker: Lucia Sarchiapone (LNL)
        Slides
      • 18
        LOW-LEVEL/HIGH-LEVEL – HOW AND WHY THE RF SYSTEM IS CHANGING AT INFN-LNS
        The INFN-LNS RF system can be considered a sort of continuous work in progress, since the commissioning of the k-800 superconducting cyclotron, more than 20 years ago. We would like to show the most important changes, upgrades and improvements of the entire RF system, related to the low level, high level and mechanics. Some of the improvements are related to the system’s age, to the outmodedness of important spare parts, like in the case of the High Level System, but some are related to modifying the system to achieve better performance, like in a few mechanical components of the cavities. Some improvements regard the low level system, to keep up with electronic innovations and, more importantly, to follow the requests and suggestions of the accelerator operators, in order to have, especially in the phase of tuning the entire cyclotron, a clear RF control panel where all the main parameters are displayed and the RF operation becomes easy, intuitive and, in the event of failures, the feedback is immediate. This progressive changing of the RF system is shown in this work.
        Speakers: Alberto Longhitano (LNS), Antonino Caruso (LNS)
        Slides
    • 13:05
      Lunch Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • Session 5 Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
      • 19
        Design and study of the 8kW Diagnostic Box for the SPES proton beam line
        The SPES project (Selective Production of Exotic Species) is a second-generation ISOL facility under construction at the LNL. The aim is the production of radioactive ion beams on the neutron rich side of the nuclide chart for nuclear structure and reaction studies, astrophysics research and interdisciplinary applications. The heart of the facility is the multi-foil UCx target where the fission of the uranium atoms induced by a 40 MeV proton beam occurs. The 8 kW of beam power delivered to the target produces about 1013 fissions per second and maintains the target at high temperatures, on the order of 2200°C, to let the products effuse out of the disks and diffuse to the ion source. In this talk, the studies carried out on the target and the beam properties requested will be presented and some of the possible failure scenarios on the beam managing discussed. On the other hand, the overall assembly on the proton beam line inside the production bunker will be analysed inasmuch it has to support the beam and characterize it. The main constraints on the design were the dissipation of the beam power, the overall dimensions and the high radioactive environment due to the huge neutron flux produced by the uranium irradiation.
        Speaker: Alberto Monetti (LNL)
        Slides
      • 20
        Magnetron sputtering for corrosion protection of liquid cyclotron target for Fluorine-18 production
        Chemically inert coatings on Havar® entrance foils of the liquid cyclotron targets for Fluorine-18 production are needed to decrease the amount of ionic contaminants released from Havar®. For efficient corrosion protection, both chemical inertness and microstructure of the coating are important. The corrosion damage of coated entrance foils is caused mainly by the diffusion of highly reactive products of water radiolysis through the protective film toward Havar® substrate. Since amorphous metal alloys (metallic glasses) are well known to perform a high corrosion resistance, the glass forming ability, microstructure and diffusion barrier efficiency of binary alloys containing Nb, Ta, Zr were investigated. Preliminary study of the co-sputtered Nb–Ta, Nb–Zr and Ta–Zr films of different alloy composition was realized in order to define the glass forming abilities. Though co-sputtered Nb–Ta and Nb–Zr alloy films of different contents were crystalline, Ta–Zr alloy was found to form amorphous microstructures in a range of composition with 30–73% atomic Ta. Diffusion barrier efficiency tests used reactive aluminum underlayer and protons of HCl solution as corrosion inducing particles. The diffusion barrier efficiency of Nb–Zr and Nb–Ta alloy coatings decreased with increase of Nb content. The diffusion barrier efficiency of sputtered Ta–Zr alloy coatings increased with the transition from nanocrystalline columnar microstructure to amorphous for coatings with 30–73 at.% Ta. In the next step, the properties of TaZr (1:1) protective films deposited from mono-target by magnetron sputtering were studied. The deposition parameters were optimized in order to provide dense amorphous coating with minimal level of intrinsic stress. The TaZr (1:1) coating is to be sputtered onto planar Havar® foils for Fluorine-18 target of IBA CYCLONE 18/9.
        Speaker: Hanna Skliarova (LNL)
        Slides
      • 21
        Experimental set-up for thermal resistance at interface measurements
        To increase the production yield of radioisotope of medical interest, elevated particle currents are required. This is associated with elevated thermal power that should be dissipated by appropriate cooling system. The conventional solid cyclotron target for medical radioisotope production is cooled with circulating water from the back and helium gas turbulent flow from the front (optional). The water cooling system can be of two types: open circuit, when the water is in direct contact with the backing plate of the target, and closed circuit, when heat exchange is realized through the contact between the backing plate and water-cooling chamber. The closed circuit approach is providing easy target manipulation and less problem with activated water, but is limited by the thermal resistance at the interface. Several models in order to predict the thermal resistance were developed but they are not in agreement with each other and not proved by experiments. During current study, an experimental set-up was developed in order to measure the thermal resistance at the interface between different materials in respect to the quality of the contact. The first measurements of the thermal resistance at interface between two copper samples in respect to the contact pressure were realized. The thermal resistance at interface of copper with standard lathe machining is at the range of 7E-05 K·m2/W for 1.3 MPa and 4E-05 K·m2/W for 4.2 MPa in the contact. In future other parameters influencing the performance of the heat exchange, will be tested, such as the aging (the oxidation level of the samples), the roughness of the surface in contact and different materials. These results will help to define the concept for the high power target station for 70 MeV cyclotron at LNL-INFN.
        Speaker: Sara Cisternino (LNL)
        Slides
    • 15:45
      Coffee-Break and Poster Session Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • 16:30
      Bus to Padova, Piazza Eremitani Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • 17:15
      Visit to Scrovegni Chapel Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • 19:15
      Bus to Restaurant Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • 20:00
      Social Dinner Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy

      Restaurant Liviangior, Abano Terme (Padova)

    • 22:30
      Bus to Padova Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • 08:15
      Bus to LNL Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • Session 6 Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
      • 22
        Management Software and Data Exchange Protocol for the INFN-LNS Accelerators Beamlines
        My presentation will describe the design and the development of an innovative management software for the accelerators beamlines at INFN-LNS. The Graphical User Interface, the data exchange protocol, the software functionality and the hardware will be illustrated. Compared to traditional platforms for the accelerators console, at INFN-LNS we have developed a new concept of control system and data acquisition framework, based on a data structures server which so far has never been used for supervisory control. We have chosen Redis as a highly scalable data store, shared by multiple and different processes. With such system it is possible to communicate cross-platform, cross-server or cross-application in a very simple way, using very lightweight libraries. A complex and highly ergonomic Graphic User Interface allows to control all the parameters with a user-friendly interactive approach, ensuring high functionality so that the beam operator can visually work in a realistic environment. All the information related to the beamline elements involved in the beam transport, can be stored in a centralized database, with suitable criteria to have a historical database.
        Speaker: Gianfranco Vecchio (LNS)
        Slides
      • 23
        Correction of nu_r-nu_z=1 Resonance in TRIUMF Cyclotron
        The second order linear coupling resonance $nu_r-nu_z$=1 is driven by an asymmetry in the median plane of the cyclotron due to presence of the first harmonic in $B_r$. In TRIUMF cyclotron, this resonance is encountered at about 166\,MeV and 291\,MeV, where $\nu_r\simeq 1.2$ and $\nu_z \simeq 0.2$. When the beam is off-centered radially to pass through this resonance, the radial oscillation gets converted into vertical oscillation, which can cause beam loss to occur, though these loss modes do not reduce the machine transmission under normal operation. In this paper, we present the results of simulations and measurements that we have performed to correct this resonance by using the existing harmonic coils.
        Speaker: YI-NONG RAO (TRIUMF)
        Slides
      • 24
        Investigation on the spiral inflector and central region of the IsoDAR test bench cyclotron
        The IsoDAR project aims to perform searches for the sterile neutrino looking at intense neutrino source placed near the neutrino detector of Kamland. The neutrinos are produced by the collision between 10 mA proton beam and a target, leading to the generation and subsequent decay of 8Li. The proton beam will be produced by a cyclotron able to accelerate a 5 mA H2+ up to the energy of 60 AMeV. The H2+ ions will be extracted using an electrostatic deflector. Due to the high beam intensity, the design of the injection and of central region is a key issue for the IsoDAR cyclotron since the space charge effects play an important role in the beam dynamics both along the injection line and the central region, included the spiral inflector. As the beam injection and the central region are challenging items for IsoDAR cyclotron, a 1 AMeV test bench cyclotron is being designed to study and test either the beam injection from the ion source into the cyclotron and the acceleration in the first turns of the machine. An overview of the IsoDAR test cyclotron is presented. In addition, the preliminary results of the simulations of the spiral inflector and the central region design for the test bench cyclotron, realized at IBA, are shown. Particular attention has been given to the space charge calculations during the present study.
        Speaker: Grazia D'Agostino (LNS)
        Slides
      • 25
        Final design of the SC202 superconducting cyclotron for hadron therapy
        The physical design of the compact superconducting cyclotron SC202 for proton therapy has been finished. Two copies of SC202 will be manufactured, according to the agreement between JINR (Dubna, Russia) and ASIPP (Hefei, China). First copy will be used for proton therapy in Hefei, and the second copy will be used to replace “Phasotron” in the research and treatment program by at JINR. Parameters of main systems and final schemes of extraction systems different for the Hefei cyclotron and the Dubna cyclotron are presented.
        Speaker: Oleg Karamyshev (Joint Institute for Nuclear Research)
    • 10:40
      Coffee-Break Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • Session 7 Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
      • 26
        The AISHA Ion Source: Commissioning and preliminary results
        The AISHa ion source is an Electron Cyclotron Resonance Ion Source designed and developed for the generation of high brightness multiply charged ion beams with high reliability, easy operations and maintenance for feeding linear accelerator or cyclotrons. Its innovative magnetic field is provided by a Halbach-type permanent magnet hexapole (radial confinement) and for four high field He-free superconducting magnets (longitudinal confinement). This hybrid solution allows to get higher performances limiting manufacturing and maintenance costs. The present work shows the preliminary results of the AISHa commissioning, either in terms of total current (up to 18 mA extracted from the source) and in terms of charge state distribution. Next steps for the upgrade of the AISHa source to full power conditions will be also commented.
        Speaker: David Mascali (LNS)
      • 27
        DECRIS-PM ion source for the DC-280 cyclotron
        A new all-permanent magnet ECR Ion source DECRIS-PM had been developed to be used at the high voltage platform of DC-280 cyclotron. The source has been designed at the FLNR JINR (Dubna) in collaboration with the “ITT-group” company (Moscow, Russia). The operating frequency selected to be 14 GHz for the source. The corresponding values of Binj, Bmin and Br were chosen according to scaling laws for the axial magnetic field configuration. The injection magnetic field maximum was chosen to be around 1.3 T to have a reasonable weight of the system and basing on the earlier experience of conventional ion sources. Combination of the permanent magnet rings and soft iron plates makes the magnetic structure flexible, and provides the possibility of magnetic field correction during assemblage stage. Other specific feature of the source is an additional coil placed at the center of the structure between the hexapole and central PM ring. The coil will be used to tune the Bmin value during the source operation. Presently the source is under tests at the test bench. In the first experiments the intense beams of Ar8+ (920 eµA), Ar11+ (200 eµA), Ar12+ (150 eµA), Kr15+ (180 eµA) and Kr17+ (125 eµA) were produced. The source is also tested for production of metal ion beams (Mg, Ca and Fe).
        Speaker: Sergey Bogomolov (JINR)
        Slides
      • 28
        H2+ beams for Cyclotrons
        Several projects will require high beam current for H2+either for neutrino factories and for applications. Different strategies have been envisaged, including overdense plasmas in microwave discharge ion sources (MDIS) and the recent developments in terms of production of high current high stability beams are satisfactory. The paper will describe the state of the art and the future optimization of the PS-ESS source, designed for protons, in order to fulfill the requirements of the above cited projects. In particular, the trial for correlating the relative H2+/p abundance inside the plasma (by optical emission spectroscopy) and in the beam will be discussed.
        Speaker: Giuseppe Castro (LNS)
      • 29
        Status of a new 18 GHz ECRIS HIISI
        The Accelerator Laboratory at the University of Jyvaskyla (JYFL) has performed radiation effects testing of electronics since 1998 using a K130 cyclotron and cocktail beams produced with ECR ion sources (ECRIS). Currently most of the tests are done at 9.3 MeV/u energy which is achievable with the charge states produced by the 14 GHz ECRIS of the laboratory. The radiation effects community has shown a strong desire to reach 15 MeV/u, which is approaching the limits of achievable charge states without superconducting ECR technology using the K130 cyclotron, i.e. requiring ions with m/q < 3. A high-energy cocktail has been proposed to be used at JYFL with Xe 44+ as the heaviest component. Production of such very high charge states have so far been demonstrated only with fully superconducting ECRIS, e.g. 18 GHz SUSI at MSU. The desire for the very high charge states has initiated a project to push the performance of normal conducting ECRIS by developing an 18 GHz ECRIS HIISI (Heavy Ion Ion Source Injector). The new ion source being developed features several novel ideas to reach the high magnetic fields required for the production of the highest charge states: The permanent magnet hexapole is refrigerated down to -20 C allowing the use of high-remanence, low-coercivity permanent magnet grade N45SH otherwise unusable in such application. The cooling also increases the remanence of the magnets by up to 5% compared to room temperature. The source has a non-cylindrical plasma chamber with 5 mm deep grooves on the magnetic poles to increase the radial mirror ratio within the plasma flux. The injection field has been optimized using a structure with magnetic steel plug with a Permendur tip and a magnetic steel bias disc. The source has three coils allowing tuning of Bmin independently of Binj and Bext. At nominal solenoid currents of Iinj/Iext/Imiddle = 1000/820/-300 A the field values are Binj=2.80 T, Bext=1.30 T,Bmin=0.42 T and Brad=1.32 T. The plasma can be heated using microwaves from three separate waveguide ports for 18 GHz klystron, 14 GHz klystron and 11-18 GHz TWTA, with a total microwave power capacity of 5 kW. The commissioning is under way. The first beam from the new ion source was extracted in May 2017. So far the source has produced 160 uA of oxygen 7+ beam with 600 W of microwave power. The design of the 18 GHz ECRIS is presented together with the most recent results producing high charge-state oxygen and xenon beams.
        Speaker: Taneli Kalvas (University of Jyvaskyla)
        Slides
      • 30
        Concluding Remarks
        Speaker: Mario Maggiore (LNL)
    • 13:05
      Buffet Lunch Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy
    • 14:30
      Bus to Padova Sala Villi

      Sala Villi

      INFN Laboratori Nazionali di Legnaro

      Viale dell'Università 2, Legnaro PD, Italy