1. DAF Distributed Accelerator Facility (DAF) Transnational Access Nodes: 1.Tandem Accelerator Laboratory, Rudjer Boskovic Institute (RBI), Zagreb, Croatia 2.Nuclear Physics Institute, Rez, Czech Republic 3.Institute of Nuclear Physics, NCSR “Demokritos”, Athens, Greece 4.Institute of Nuclear Research, Hungarian Academy of Sciences (ATOMKI), Debrecen, Hungary 5.Heavy Ion Laboratory, Warsaw University, Poland 6.National Institute of Physics and Nuclear Engineering (IFIN-HH), Bucharest, Romania Photo JYFL ISOLDE – CERN GSI – Darmstadt GANIL Louvain-la-Neuve INFN – LNL KVI DAF

2. Transnational Access Name / Location of the infrastructure: TAL-RBI, Zagreb NPI-Rez, Prague INP-NCSR, Athens ATOMKI, Debrecen HIL, WarsawIFIN-HH, Bucharest DAF Approximate investment / replacement cost 5 M€15 M€10 M€ 40 M€20 M€ 100 M€ Annual operating cost: 136 k€875 k€400 k€ 1.2 M€400 k€ 3.4 M€ Funding sources: Croatian Ministry of Science (80%) Other (20%) Czech Ministry of Science National funding agency Hungarian Academy of Sciences (project based) Warsaw University Ministry of Science and Higher Education National funding agency National funding ( > 99%)

3. DAF Transnational Access Brief description of the accelerator infrastructure: Prague: U-120M cyclotron – H +, H  10-38 MeV 40-5  A; D +,D  10-20 MeV, 25-5  A, 3 He 17-53 MeV 3  A and 4 He 20-40 MeV 5  A; Zagreb: 6 MV EN tandem – more than 30 ion beams, among others: H, D, 3,4 He (up to 1  A, 18MeV), 10,11 B, Li, C, O and 35Cl6+ 0.5-5.5 MV and 1 MV Tandetron: protons 0.4-2.0 MeV up to 10  A, D, O; Athens: 5.5 MV Van de Graaff tandem – p, d 30  A, 4 He, Li, 1  A, C, O 15  A, F 1  A, Ti, V… 0.5  A; Debrecen: Isochroneous LI cyclotron (K = 20) – p, d, 3He, 4 He from 0.2 MeV (p) to 27 MeV (3He) max 50  A; 5 MV Van de Graaff tandem – 1,2 H+, 4 He+, C+ 1 – 10  A. Warsaw: K=160 heavy ion cyclotron – beams of gaseous elements or elements available from gaseous compounds from B to Ar at energies 2-10 MeV/A and intensities up to a few hundreds pnA; Bucharest: 9 MV FN-type tandem – 28 ion species from protons to Au with intensities up to 1  A. Major instrumentation: Unique instruments at the different nodes of DAF, e.g. a plunger device coupled to a 16 detector  -ray array, charged particle and neutron detectors at IFIN-HH, an online mass separator of IGISOL-type, the  - ray array OSIRIS II, the charged-particle multidetector system ICARE and the GDR multidetector system JANOSIK at the Warsaw cyclotron, a general purpose scattering chamber equipped with large position-sensitive silicon detector telescopes for charged particles, an experimental line for high-resolu­ tion timing with an MCP start detector and a multipurpose chamber for various stop detectors at the Rudjer Boskovic Institute, a split-pole magnetic spectrometer, SC solenoid and mini-orange spectrometers at Atomki, Debrecen, a 12  x12  4π calorimeter, 30 3 He– det array and Micromegas-type detectors at NCSR “Demokritos”, unique internal pair spectrometers and microbeam facilities at Atomki etc. Total beam time per year RBI: 1080 (6 MV Tandem) Rez: 3500 (NP: 10%) Athens: 2500 (NP: 50%) ATOMKI cyclotron: 1700; VDG: 2900 (NP: 50%) Warsow: 3000 Bucharest: 4000 (NP: 50%) DAF > 19 000 NP: 8700 Program Committee NO YESNO to be set up User OrganizationNO YES (nat.)NOYES (nat.)NO to be established

4. DAF Transnational Access RBI, Zagreb Rez, Prague NCSR, Athens ATOMKI, Debrecen HIL, Warsaw IFIN-HH, Bucharest DAF Infrastructure under EURONS: NO Access unit to be defined under EURONSII – /UT – /hour Unit cost to be defined under EURONSII: € 1000€ 700€ 1280€ 700€ 800 € 850 Access estimated per year for EURONSII – /80 – /30 – /100– /120– /150– /100 – /580 Estimated number of user projects supported per year for EURONSII – /3– /2– /4– /6– /5 – /25 Estimated number of users and person-days to be supported per year under EURONSII – /12 – /90 – /8 – /50 – /15 – /105 – /20 – /140 – /25 – /175 – /20 – /140 – /100 – /700

5. DAF Transnational Access DAF USER BASE the Central and South-eastern European nuclear physics groups; collaborations with other European groups, e.g. Ruhr University of Bochum Koeln University INT Lisbone University of Oslo INFN – Catania IPHC, University Louis Pasteur, Strasbourg University of Birmingham INP, Academy of Sciences of Ukraine, Kiev (process is underway!)

6. DAF How does DAF help to strengthen the European Nuclear Physics Research Infrastructure ? Expertise and research programme in the fields of nuclear structure physics and nuclear astrophysics Utilization of unique instruments at the different nodes of DAF The beam-time overload at the large-scale research infrastructure can be partially reduced and DAF will enable to distribute experimental projects of the community in a more economic way. Enhancement of inter-laboratory cooperation in Europe, which makes DAF an appropriate place for testing equipment, novel experimental techniques, or parts of these, and which can help to optimize these European accelerators and provide facilities for pilot experiments for the present and next generation facilities such as FAIR, SPIRAL2 and EURISOL. Transnational Access

7. DAF Transnational Access