CERN-ISCC Meeting “ Storage Ring Facility at HIE-ISOLDE ”

1. CERN-ISCC Meeting“Storage Ring Facility atHIE-ISOLDE” Klaus Blaum 3rd Nov 2011

2. Important steps:1) TSR@ISOLDE Workshop at the Max-Planck-Institute for Nuclear Physics 28.-29.10.2010 (34 participants)2) Presentation of the TSR@ISOLDE LOI at the CERN INTC- Meeting 02.02.2011 (about 60 coauthors)3) Presentation of the scientific (Yuri Litvinov) and technical Fredrik Wenander) part of the TSR@ISOLDE Project at the STORI 2011 conference4) TSR@ISOLDE Meeting at MPIK in order to discuss the open questions related to the preparation of the TDR for the INTC meeting (28.10.2011)5) TDR for the TSR@ISOLDE project almost ready for submission, which is planned for the February 2012 INTC Meeting (> 120 coauthors, about 20 institutions)

3. Presently 125 pages!

4. The heavy ion storage ring TSR at MPIK Heidelberg TSR Max Planck Institute Heidelberg Circumference: 55m TSR@HIE-ISOLDE LOI Jan 2011 TDR in progress (K. Blaum, Y. Litvinov)

5. Some technical details: • Typical storage energy for 12C6+: E = 72 MeV 6 MeV/u • Vacuum: ~10-11 mbar • Acceptance ellipse of the TSR: 120 mm mrad well suited for REX-ISOLDE • Multiturn injection  mA of stored beam possible • Electron cooler  transverse cooling time of ~1s • RF acceleration and deceleration possible • Typical storage times: p @ 21 MeV: 60 h • 9Be1+ @ 7 MeV: 16 s12C6+ @ 73 MeV: 7470 s • 35Cl17+ @ 202 MeV: 318 s • 197Au51+ @ 710 MeV: 23 s

6. Physics cases discussed in the TSR@ISOLDE TDR • Half-life measurements of 7Be in different atomic charge states • Capture reactions for astrophysical p-process • Nuclear astrophysics through transfer reactions • Nuclear structure through transfer reactions • Long-lived isomeric states • Atomic effects on nuclear half-lives • Di-electronic recombination on exotic nuclei • Atomic physics experiments • Neutrino physics • (Laser spectroscopy experiments in the storage ring)

7. Two possible locations at ISOLDE for the ring 10m restriction F/CH border F CH Courtesy of Erwin Siesling

8. Jura (west) side 24.6m 23.3m Building costs: ~ 3MCHF 8

9. Jura (west) side 23.3m 24.6m 3m Proposed layout to fit the TSR at the west side: - Installation above the CERN infrastructure-tunnel (not negotiable to move the tunnel: houses essential CERN signals and infrastructure) - Tilted beamline coming up from the machine 9

10. Surface & Weight Total surface TSR floor: 24.6x23.3m=573m2 of which 20x20m (400m2) reserved for the ring (final position of the ring within the building to be defined) TSR floor approx . 3m above Hie Linac floor Level of the center of beam at 1.77m above TSR floor 12m Total surface available basement: 12mx24.6m=295m2 to house power-supplies and additional racks (total 29m length floor space for the TSR equipment and 7m for the e-target equipment + 10 standard 19’’ racks and ECOOL HV cage 4x4m2) 10

11. Further information:Detailed estimation of the costs and manpowerrequirements are in preparation. preliminary values by MPIK exist; information from CERN neededFunding requests to the different agencies are under discussion (e.g. UK) Ideal time schedule: Building ready end of 2013,move of the ring in 2014, commissioning and start in 2015.Financial support by the ISOLDE Collaboration is needed in order to realize this project.

12. Some speculations on the EC-decay of 7Be 7Be + e- 7Li + ne 7Be + p  8B + g S. Kappertz et al., AIP Conf. Proc. Vol. 455 (1998) 110 A.V. Gruzinov, J.N. Bahcall, ApJ 490 (1997) 437 Negative magnetic moment of 7Be Ionization of 7Be in the Sun can be ~ 20-30 % TSR@ISOLDE would be the best place to perform these experiments! Y. Litvinov, MPIK and GSI

13. Reaction Studies for Astrophysical Applications Particle detectors Gas jet ESR Measurements of (p,) or (α,) rates in the Gamow window of the p-process in inverse kinematics. • Advantages: • Applicable to radioactive nuclei • Detection of ions via in-ring particle detectors (low background, high efficiency) • Knowledge of line intensities of product nucleus not necessary • Applicable to gases Proof-of-principle experiment: 96Ru (p,g)97Rh Similar experiments possible at TSR@ISOLDE!

14. Preliminary result @ 11 MeV – upper limit Ignore (p,n) component – resulting in an upper limit for (p,) σPG ~ 4.0 mb Non-smoker: 3.5 mb Similar experiments with radioactive beams feasable at HIE-ISOLDE + TSR. HIE-ISOLDE energy range fits perfectly!

15. Transfer Reaction Studies: Physics cases • Transfer around the island of inversion • 32Mg(d,p) T1/2 = 86 ms, 3103pps •  not possible (half lives) • Transfer towards 78Ni • 68Ni(d,p) T1/2 = 29 s, 5104 pps • Limit given by atomic charge exchange • Transfer around 100Sn • 102Sn(p,d) T1/2 = 4.5 s, 102 – 103 pps ?? • Could be feasible! But probably notat 10 MeV/u • Transfer around 132Sn • 134Sn(d,p) T1/2 = 1 s, 104 pps ? R. Raabe, K.U. Leuven

16. Transfer Reaction Studies: Physics cases • Shape coexistence in n-poor Pb region • Still unique @ ISOLDE(Bi, Tl never post-accelerated so far) • Beam losses?? 1E2 1E3 1E2 5E3 5E4 2E5 1E6 2E6 1E3 1E4 1E5 1E6 1E2 3E3 1E4 7E4 1E5 2E5 R. Raabe, K.U. Leuven

17. an as-yet unobserved process Nuclear Excitation by Electron Capture difficulty: NEEC competes with much stronger, but non- resonant process of radiative capture: X-ray emitted, instead of nuclear excitation. electrons nucleons electrons nucleons - nuclear analogue of dielectronic recombination - inverse of electron conversion [A. Palffy et al., Phys. Rev. Lett. 99 (2007) 172502] Proposed candidate 93Mo P. Walker, Surrey

18. Neutrino physics studies • Ideal test facility for the accumulation and storage of 6He