COMPACT WEAK FOCUSING CYCLOTRONS FOR ISOTOPE PRODUCTION: STATUS OF AMIT PROJECT Concepción Oliver [email protected] On behalf of Accelerator Unit, Division of Electric Engineering CIEMAT (Spain) Compact accelerators for isotope production 26-March-2015 INTRODUCTION   Stable nuclide Ø  PET technique is broadly used γ around the world as a diagnostic tool e- β- decay and for treatment planning and e+ γ follow-up. Positron emitting Whole-body PET scan isotope using 18F-FDG Ø  Cyclotrons are the most widely used accelerators for the production of positron emitter isotopes In Spain… 2 Workshop on compact accelerators for isotope production C. Oliver AMIT project: Advanced Molecular Imaging Technologies N O Work supported by the Spanish Ministry of Science and Innovation I T C Center for Industrial U Funded by: D Technology development O R Led by: T N I Partners: 10 companies, 14 research labs Ø Target: Development of the core technology for molecular imaging in Medicine and Biomedicine with special focus in the human brain and in particular in mental diseases WP1. Development of a compact cyclotron for 11C y 18F single doses production Ø  CIEMAT is the scientific leader of this cyclotron project q  Close collaboration with Spanish industry q  External collaborations as CERN, MIT v Funding for beam dynamics and diagnostics: OPTIMHAC, by the Spanish Ministry of Economy and Competitiveness under the project FIS2013-40860-R 3 Workshop on compact accelerators for isotope production C. Oliver THE AMIT CYCLOTRON: SPECIFICATIONS AMIT cyclotron specifications: to produce one dose of 11C or 18F N O Isotope Dose Target Reaction I T C 18F 40 mCi Water enriched in U 18O+1H+ →n+ 18F D 18O 8 1 9 O R T 11C 100 mCi Nitrogen gas 14N+1H+→4He+++11C 7 1 2 6 N I àà BBeeaamm rreeqquuiirreemmeennttss:? ?E >8.5 MeV I>10µA Ø  Very compact on-site cyclotron promises to: -  reduce cost of cyclotron (more adjustable to on-site needs) Cross sections of 11C and 18F from incident -  reduce high cost of isotope transportation to remote PET machines protons (IAEA medical database) -  possibility to produce new markers with short half- life (11C, 20 min) Ø Technology requirements for radiopharmaceuticals production: § To minimize building requirements: à compact machine - cyclotron with the minimal weight/size - Reduced shielding § Low power consumption §  Minimal maintenance Context: Experienced group in accelerator component design and fabrication but not in a complete machine development, integration and operation → Limitation of the complexity of the accelerator and its challenges. 4 Workshop on compact accelerators for isotope production C. Oliver THE AMIT CYCLOTRON: SPECIFICATIONS ⎡Q2⎤ T ≈ 48.24 B2R2(MeV) ⎢ ⎥ N A R SC ⎣ ⎦ O Compact ext High B 4 T I limitation magnet T C U D O R Resistive Magnets Superconducting Magnets T N < 2T I > 2T à superconducting J Cheap and robust J Low power consumption J Easy maintenance J No field limit J No risk of quench magnet J Only alternative for really L Field limited to iron saturation compact cyclotrons level (1.8 T). L Higher power consumption. L Needs for cryogenics L Limits the minimum size of L Specific maintenance the cyclotron Simple model NbTi Technology B Biot & Savart Law Bc 3000 SC Price h 2500 Amptere´s Law H p ht (kg) 12500000 POT 2205000000 Weig 1000 E uros 15000 SC  Price z Bs E 10000 c Bo g 500 re 5000 r 0 0 rpi 0 2 4 6 8 0 2 4 6 8 B (T) re B (T) o à 4 Tesla for NbTi 5 Workshop on compact accelerators for isotope production C. Oliver Why classical machines (again)? E. Lawrence 6 Workshop on compact accelerators for isotope production C. Oliver AMIT CYCLOTRON BB zz Beam focusing in cyclotrons: BB OO N O rr o  Focusing by radially I 000 rrreee T decreasing magnetic field C BB U OO o  Non synchronism D θθ O 000 222πππ R T N I BBB zzz o  Focusing by an rrr 0000 rrrreeee alternating field (flutter) in BB00++ΔΔBB BB00 azimuthal direction F= 1 2∫π⎢⎡B(r)−B0⎥⎤2dθ BB00--ΔΔBB 2π B θθθ 0⎣ 0 ⎦ o  Synchronism 0000 2222ππππ q  In our 4T cyclotron, the magnetic field is so high that iron will be saturated and the magnetic field difference between valleys and hills is small, resulting in a small flutter (even with spiralized sectors) q  Other solutions (magnetic elements with higher saturation level, additional SC coils) will result in expensive or more complicated machines q  Classical cyclotron becomes a good option for compact machine, given its simplicity Focusing forces: Compact low flutter for a Classical Machine: 4 T 4 T isochronous Cyclotron machine 7 Workshop on compact accelerators for isotope production C. Oliver N O I T Classical AMIT Requirements C U cyclotron D O R T N I Iterative process Beam Dynamics Vacuum system & diagnostics 8 Workshop on compact accelerators for isotope production C. Oliver AMIT BEAM DYNAMICS IN A CLASSICAL CYCLOTRON Non particle-RF isochronism q  The energy gain will be lower than the maximum one (qV ) peak q  The time that the particle can be accelerated is limited–> limitation on the maximum energy at extraction in a classical cyclotron To optimize the AMIT radioisotope production ß I, E I extracted by puller q  High accelerating voltages à higher energy gain & higher extracted current by pullerà 60 kV q  Limited field gradient of magnetic field à balance between beam focusing and phase shift Relative Radioisotope production q  Optimum phase excursion: maximum excursion for 60.3 0.9 0.8 60.25 max. energy but limited to avoid losses by vacuum stripping 0.7 60.2 z) 0.6 H 60.15 and by electric defocusing forces à Beam tuning with RF M 0.5 F ( R 60.1 0.4 0.3 frequency (B field) and stripping foil location 60.05 0.2 60 0.1 59.95 0 q  Careful design of central region à given the internal 0.08 0.09 0.1 0.11 Stripper radial position (m) ion source, high B & V and weak focusing magnetic forces Workshop on compact accelerators for isotope production C. Oliver AMIT cyclotron: main specifications N O I GENERAL T C Cyclotron Type Classical U Energy >8.5 MeV D O Current >10 µA R MAGNET T N Type Low Tc Superconductor I Configuration Warm Iron Superconductor NbTi Central Field 4 T Radially decreasing (1.5%@extraction Focusing type radius) RF SYSTEM Configuration One 180º Dee Peak Voltage 60 kV RF frequency ∼ 60 MHz ION SOURCE Type Internal Ions H- EXTRACTION Extraction Stripping foil at 110 mm Nitrogen gas (11C) , 18O enriched water Target (18F) Position External 10 Workshop on compact accelerators for isotope production C. Oliver