1. * Spokesperson: Isao Tanihata - Beijing and Osaka Co-spokesperson: Hans Geissel – GSI Chair of Collaboration board: Juha Äystö – Helsinki Co-chair: Christoph Scheidenberger

3. FAIR Experiments Günther Rosner2nd ECE Mtg., Darmstadt, 21/6/133 CBM PANDA APPA NUSTAR

4. Scientific Program of the Super-FRS Collaboration Report of the collaboration to the FAIR management Darmstadt, May 26, 2014

6. Take advantage of E>1500 A MeV 238 U; cross section and kinematics. High-energy and high-intensity primary and secondary nuclear beams with energies up to 1,500 A MeV. Unique high-energy, high momentum-resolution multiple-stage spectrometer with large acceptance and flexible ion-optical settings, including the energy-buncher of the LEB. High primary-beam suppression power and high separation power of nuclides up to Z=92, and fully stripped ions of all elements. Versatile spectrometer modes by different combinations of separator sections, coupled to advanced tracking (GEM-TPC, diamond,Si,…)

7. Super-FRS scheme

8. Science Topics Super-FRS for high mass and charge resolution (early stage) 1. Rare isotope yields, ground state properties & limits of nuclei 2. Understanding atomic collisions at relativistic energies Super-FRS as high-energy and high-resolution spectrometer 3. Spectroscopy of meson-nucleus bound system (mesonic atoms) 4. Exotic hypernuclei and their properties 5. Importance of tensor forces in nuclear structure 6. Delta resonances probing nuclear structure (Benlliure, 2C) Super-FRS as a multi-stage separator and spectrometer 7. Nuclear radii and momentum distributions 8. In-flight radioactive decays and continuum spectroscopy by particle emission (Pfützner, 4A & Fomichev. PS1-139) 9. Low-q experiments with an active target 10. Reaction studies and synthesis of isotopes with low-energy RIB

9. Experimental modes of Super-FRS

10. Search for new isotopes and the limits of bound nuclei produced in fission and fragmentation. Take advantage of E>500A MeV 238 U or other beams. Many new isotopes to be produced in fission, transfer and fragmentation. Part of commissioning phase (performance, ion optics, tracking,..) The determinations of production cross sections of unstable nuclei are imperative for entire Super-FRS operation. Stopped beam physics (CGC & MRTOF). Key region for Super-FRS J. Kurcewicz et al. Phys.Lett. B 717,371(2012) T. Kurtukian-Neito et al. Phys. Rev. C 89, 024616 (2014)

11. Exotic (n-rich) hypernuclei and their properties Production of hypernuclei at high-energy (>1.2A GeV) heavy-ions peripheral collision is expected to have large cross sections. The method is also suitable for determination of lifetimes of hypernuclei via weak decay channel (Λ free  p  - or n  0,  0.26 ns) (Lorentz factor on lifetime !)  Pilot experiment at FRS (HypHI) shows evidences of 3 Λ Η, 4 Λ Η, 3 Λ n C. Rappold et al Phys. Rev. C 88(2013)041001 A. Botvina et al Phys Rev C 88(2013)054605 The lifetimes have also been determined. Higher mass resolution of Super-FRS will help for identifications. Strangeness sector of nuclear chart

12. Delta resonances probing nuclear structure Charge changing reactions with high-energy heavy ions provide unique possibilities to study baryon resonances, including Δ- resonances, in exotic nuclei (  S=1,  I=1 excitations). So far Δ-resonances in nuclei have been studied exclusively in stable or near stable nuclei Δ(1232) 112 Sn( 63 Cu,X) 112 Sb Studying In-medium properties of baryon resonance in isospin asymmetric nuclear matter Gamow-Teller transition strength Radial distribution of neutrons and protons Nuclear matrix elements for inelastic neutrino interactions (Benlliure, session 2C) Energy loss spectrum of 112 Sb

13. Low-energy reaction studies with RiBs Will be done at Low-Energy Beam line, employing the energy buncher. Will challenge at and above Coulomb-barrier energies a new field for reaction studies. Will contribute to a better understanding of deep inelastic, fusion-fission and complete fusion reactions. Potentially serves for the extension of the nuclear chart to regions not accessible in fusion reactions with stable beams nor in fragmentation reactions.

14. Conclusions  The scientific program presented is largely unique orcomplementary within the NUSTAR collaboration.  It is unique in the world when compared with the goals ofother next-generation exotic nuclear beam facilities.  It is in line with the scientific goals of FAIR and with theproposed scope of the Modularized Start Version.  The collaboration is open to, and exploits synergies withthe scientific and technical programs of the other FAIRcollaborations, in particular with APPA, CBM and PANDA.

15. List of topic conveners for Super-FRS Physics case Rare isotope search experiments (Pietri, Jokinen, Plaß et al.) Atomic collision experiments (Purushothaman, Geissel et al.) Mesonic atoms and in-medium effects (Itahashi, Weick et al.) Exotic hypernuclei and their properties (Saito, Nociforo et al.) Exploration of tensor force (Ong,Terashima, Toki, et al.) Delta resonances probing nuclear structure (Benlliure, Lenske et al.) Nuclear radii and momentum distributions (Kanungo, Prochazka et al.) Exotic radioactivity modes (Fomichev, Pfützner, Mukha et al.) Low-q experiments with Active Target (Egelhof, Kalantar et al.) Low energy reactions (Heinz, Winfield et al.)