The Miniball experiment is a gamma-ray spectroscopy setup regularly located in the ISOLDE facility at CERN, along with other locations including GSI, Cologne, PSI and RIKEN (HiCARI).[1][2][3][4] Miniball is a high-resolution germanium detector array, specifically designed to work with low-intensity radioactive ion beams post-accelerated by HIE-ISOLDE (High Intensity and Energy-ISOLDE), to analyse gamma radiation emitted by short-lived nuclei. Due to six-fold detector segmentation, Miniball offers a superior Doppler-correction capability with respect to conventional gamma-ray spectrometers using unsegmented detectors. The array has been used for successful Coulomb-excitation and transfer-reaction experiments with exotic beams. Results from Miniball experiments have been used to determine and probe nuclear structure.[5]

Isotope Separator On Line Device
(ISOLDE)
List of ISOLDE experimental setups
COLLAPS, CRIS, EC-SLI, IDS, ISS, ISOLTRAP, LUCRECIA, Miniball, MIRACLS, SEC, VITO, WISArD
Other facilities
MEDICISMedical Isotopes Collected from ISOLDE
508Solid State Physics Laboratory
Miniball experimental setup at the ISOLDE facility (CERN)

Miniball has been operational at the REX-ISOLDE (Radioactive ion beam EXperiment-ISOLDE) post accelerator at CERN since 2001.[6] In 2015, it became part of the HIE-ISOLDE project, connected via the XT01 beamline.[7] It was the first fully operational germanium gamma-ray spectrometer capable of determining spatial coordinates of the gamma-ray interaction points within the detector volume using pulse shape analysis.[8]

Background

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The main two reaction mechanisms used in experiments with the Miniball setup at ISOLDE are Coulomb excitation and transfer reactions (mostly one- and two-neutron transfer).

Coulomb excitation is a technique used to probe the electromagnetic (EM) aspect of nuclear structure. A nucleus is excited by an inelastic collision with another nucleus; to ensure that there is no contribution to the excitation process from the short-range nuclear force, a sufficiently large distance of closest approach of the colliding nuclei is required. The nucleus then decays to a lower state, emitting a gamma ray which can be detected using gamma-ray detectors.[9] This method is useful for investigating collectivity in nuclei (motions of individual nucleons are correlated), as collective excitations are often connected by electric quadrupole transitions.[10]

 
Transfer reaction of projectile and target nucleus

During transfer reactions, one (or more) nucleons are exchanged between the target nucleus and the projectile, resulting in a different final state nucleus.[11] Measurements of the emission angle and energy for use in two-body kinematic calculations can give the excitation energy of the populated states in the final state nucleus. Additionally, the measured angular distributions are compared to theory to deduce the transferred orbital angular momentum in the reaction. For single-nucleon transfer, this indicates the orbital that the nucleon has been transferred into. Studying transfer reactions is useful in nuclear astrophysics as it replicates stellar evolution and can test theoretical models.[12]

Experimental setup

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Overhead view of the Miniball set up

The Miniball detector array consists of 24 high-purity germanium crystals which have a tapered front end.[8] In contrast to other detectors developed at a similar time (e.g. EUROBALL) they have a six-fold segmentation, with each of the segments coupled to a separate preamplifier.[13] The crystals are sealed in an aluminium can, allowing access of the cold electronics without the use of a cleanroom, as the fragile surface of the germanium crystal is protected by the can.[6][5]

The encapsulated crystals are six-fold segmented and housed in cryostats that make it possible to cool down the crystals using liquid nitrogen. Each cryostat is shared by three capsules, which are installed in a common vacuum chamber connected to a single dewar. Depending on the dimensions of the reaction chamber placed in the centre of the array, the clusters can be arranged in various configurations to provide optimum solid angle coverage.[14] This is achieved by mounting cryostats on half-circular, rotatable arms with the ability for continuous motion along the arms.[5]

 
CD detector used at Miniball at CERN

The T-REX (Transfer at REX) setup is designed for measuring transfer reactions at the Miniball detector. The setup consists of a silicon barrel with forward and backward CD detectors, covering a solid angle of 66% of 4π. The T-REX measures the angular distribution of the light reaction products.[11]

Miniball uses digital pulse processing by using real-time digital filter algorithms to produce results for energy and time. The data acquisition and analysis system consists of a front-end system for data readout and transport, and a back-end system for control and data analysis.[1]

Results

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A result from the Miniball experiment at ISOLDE was listed among the Institute of Physics (IoP) "top 10 breakthroughs in physics" for 2013.[15] The research found evidence that a heavy nucleus, namely radium-224, has a rigid pear shape.[16] The breakthrough was also featured as the cover of one of the issues of Nature in 2013.[17]

The main experimental technique used with Miniball is low-energy Coulomb excitation. Using this technique, electric dipole, quadrupole and octupole moments of electromagnetic transitions in several radioactive nuclei have been determined.[18] The technique of transfer reactions is also used in Miniball experiments.[11] As an example, in one of the first transfer-reaction experiments performed with Miniball an excited state of spin-parity 0+ having a spherical shape has been identified in the "island of inversion" nucleus 32Mg.[19][6]

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References

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  1. ^ a b Reiter, P.; Eberth, J.; Faust, H.; Franchoo, S.; Gerl, J.; Gund, C.; Habs, D.; Huyse, M.; Jungclaus, A.; Lieb, K. P.; Scheit, H.; Schwalm, D.; Thomas, H. G.; van Duppen, P.; Weisshaar, D. (2002-04-22). "The MINIBALL array". Nuclear Physics A. 5th International Conference on Radioactive Nuclear Beams. 701 (1): 209–212. Bibcode:2002NuPhA.701..209R. doi:10.1016/S0375-9474(01)01576-7. ISSN 0375-9474.
  2. ^ "Miniball documentation page". www.ikp.uni-koeln.de. Retrieved 2023-08-11.
  3. ^ "muX | LTP | Paul Scherrer Institut (PSI)". www.psi.ch. Retrieved 2023-08-16.
  4. ^ Wimmer, K; Doornenbal, P; Aoi, N; Baba, H; Browne, F; Campbell, C; Crawford, H; De Witte, H; Fransen, C; Hess, H; Iwazaki, S; Kim, J; Kohda, A; Koiwai, T; et al. (2021). "HiCARI: High-resolution Cluster Array at RIBF" (PDF). RIKEN Accelerator Progress Report. 54.
  5. ^ a b c Warr, N.; Van de Walle, J.; Albers, M.; Ames, F.; Bastin, B.; Bauer, C.; Bildstein, V.; Blazhev, A.; Bönig, S.; Bree, N.; Bruyneel, B.; Butler, P. A.; Cederkäll, J.; Clément, E.; Cocolios, T. E. (March 2013). "The Miniball spectrometer". The European Physical Journal A. 49 (3): 40. Bibcode:2013EPJA...49...40W. doi:10.1140/epja/i2013-13040-9. ISSN 1434-6001.
  6. ^ a b c Reiter, P.; Warr, N. (2020-07-01). "Nuclear structure studies with re-accelerated beams at REX-and HIE-ISOLDE". Progress in Particle and Nuclear Physics. 113: 103767. Bibcode:2020PrPNP.11303767R. doi:10.1016/j.ppnp.2020.103767. ISSN 0146-6410. S2CID 213422435.
  7. ^ Borge, M. J. G.; Riisager, K. (2016-11-17). "HIE-ISOLDE, the project and the physics opportunities". The European Physical Journal A. 52 (11): 334. Bibcode:2016EPJA...52..334B. doi:10.1140/epja/i2016-16334-4. ISSN 1434-601X. S2CID 254112292.
  8. ^ a b Schwalm, D. (March 2005), "First Experiments with Rex-Isolde and Miniball", Key Topics in Nuclear Structure, World Scientific, pp. 21–34, Bibcode:2005ktns.conf...21S, doi:10.1142/9789812702265_0003, ISBN 978-981-256-093-3, retrieved 2023-08-02
  9. ^ Zielinska, Magda (27 Jan 2016). "Theoretical description of low-energy Coulomb excitation" (PDF). indico.cern. Retrieved 2 Aug 2023.
  10. ^ Clément, E.; Zielińska, M.; Péru, S.; Goutte, H.; Hilaire, S.; Görgen, A.; Korten, W.; Doherty, D. T.; Bastin, B.; Bauer, C.; Blazhev, A.; Bree, N.; Bruyneel, B.; Butler, P. A.; Butterworth, J. (2016-11-28). "Low-energy Coulomb excitation of Sr 96 , 98 beams". Physical Review C. 94 (5): 054326. Bibcode:2016PhRvC..94e4326C. doi:10.1103/PhysRevC.94.054326. hdl:10852/66640. ISSN 2469-9985.
  11. ^ a b c T-REX Collaboration; Bildstein, Vinzenz; Gernhäuser, Roman; Kröll, Thorsten; Krücken, Reiner; Wimmer, Kathrin; Van Duppen, Piet; Huyse, Mark; Patronis, Nikolas; Raabe, Riccardo (June 2012). "T-REX: A new setup for transfer experiments at REX-ISOLDE". The European Physical Journal A. 48 (6): 85. Bibcode:2012EPJA...48...85B. doi:10.1140/epja/i2012-12085-6. ISSN 1434-6001. S2CID 119716833.
  12. ^ Ingeberg, V W; Siem, S; Wiedeking, M; Choplin, A; Goriely, S; Siess, J; Abrahams, Arnswald; Bello Garrote, F; Bleuel, D L; Cederkall, J; Christoffersen, T L; Cox, D M; De Witte, H; Gaffney, L P; Gorgen, A (14 Jul 2023). "Nuclear Level Density and γ-ray Strength Function of 67Ni and the impact on the i-process". arXiv:2307.07153 [nucl-ex].
  13. ^ Thirolf, P G; Habs, D; Rudolph, D; Fischbeck, C; Schwalma, D; Ebethb, J; Gutknechtc, D. "The MINIBALL-Project". {{cite journal}}: Cite journal requires |journal= (help)
  14. ^ Butler, P A; Cederkall, J; Reiter, P (2017-04-01). "Nuclear-structure studies of exotic nuclei with MINIBALL". Journal of Physics G: Nuclear and Particle Physics. 44 (4): 044012. Bibcode:2017JPhG...44d4012B. doi:10.1088/1361-6471/aa5c4e. ISSN 0954-3899.
  15. ^ iopp (2013-12-13). "Top 10 physics breakthroughs for 2013 announced". IOP Publishing. Retrieved 2023-08-11.
  16. ^ "Nuclear physics goes pear-shaped". Physics World. 2013-05-08. Retrieved 2023-08-11.
  17. ^ "Nature - Volume 497 Issue 7448, 9 May 2013". Nature. 2013-05-08. Retrieved 2023-08-11.
  18. ^ Van Duppen, P; Riisager, K (2011-02-01). "Physics with REX-ISOLDE: from experiment to facility". Journal of Physics G: Nuclear and Particle Physics. 38 (2): 024005. Bibcode:2011JPhG...38b4005V. doi:10.1088/0954-3899/38/2/024005. ISSN 0954-3899. S2CID 123521877.
  19. ^ Wimmer, K.; Kröll, T.; Krücken, R.; Bildstein, V.; Gernhäuser, R.; Bastin, B.; Bree, N.; Diriken, J.; Van Duppen, P.; Huyse, M.; Patronis, N.; Vermaelen, P.; Voulot, D.; Van de Walle, J.; Wenander, F. (2010-12-13). "Discovery of the Shape Coexisting 0 + State in Mg 32 by a Two Neutron Transfer Reaction". Physical Review Letters. 105 (25): 252501. arXiv:1010.3999. Bibcode:2010PhRvL.105y2501W. doi:10.1103/PhysRevLett.105.252501. ISSN 0031-9007. PMID 21231582. S2CID 43334780.