New experimental methods for studies of exotic nuclear systems were developed by scientists at the Flerov Laboratory of Nuclear Reactions JINR at ACCULINNA-2 facility – new fragment separator with great potential at
U-400M heavy-ion accelerator. The first experiments with radioactive beams of ⁶Не, ⁸Не, ⁹Li, ¹⁰Ве, ²⁶P and ²⁷S suggest a possibility of resolving a wide range of tasks in modern nuclear physics: production and investigation of light exotic systems (Z < 16) located beyond the limits of nuclear stability, including the studies of their rare decay modes; search for new heavy isotopes with Z=94-107 and measurement of their fission barriers. The developed methods are also applicable to a number of astrophysical tasks, for example, about the question of origin of some elements in the Universe.

The publication cycle called “Development and application of new experimental methods at ACCULINNA-2 fragment separator” was awarded with the second JINR Prize for 2020, in category Physics Instruments and Methods. Co-authors name list was the following: A.A. Bezbakh, M.S. Golovkov, А.V. Gorshkov, S.A. Krupko, I.A. Muzalevskii, G.M. Ter-Akopian, A.S. Fomichev, V. Chudoba, G. Kaminski (all employed in FLNR JINR) and E.Yu. Nikolskii (NRC KI, FLNR JINR).

Fig.1. Layout of the ACCULINNA-2 fragment separator at the U-400M cyclotron hall

In 2017, a new unique facility, the ACCULINNA-2 fragment separator located at the
U-400M heavy-ion accelerator, was launched at FLNR, see Fig.1. Commissioning of the separator, performed by means of the fragmentation of the ¹⁵N primary beam on the 2 mm beryllium target, demonstrated that the achieved properties of the produced secondary beams of radioactive ions (RI) are fully consistent with the stated parameters. In 2018, methodical works aimed at to perform full scale experiments with RI beams ⁶Не, ⁸Не, ⁹Li, ¹⁰Ве, etc. [1-5] were carried out.

Flagship experiment was aimed at search for ⁷Н system characterized by extremely large neutron excess. The reaction ⁸He (26 MeV per nucleon) + d → ³He + ⁷H was chosen for population of the ⁷Н states. A registration of low-energy ³Н recoils in coincidence with fast tritons (E ~ 70 ± 30 MeV), emitted at very forward angles in a narrow cone Theta ≤ 6° was crucial for the identification of the ⁷Н events. It was necessary to detect such tritons with angular resolution ~ 0,5° and energy resolution better than 2%. For this purpose, the triton telescope, consisting of the 1.5 mm thick silicone double side detector and 4×4 array of CsI(Tl)+PMT detectors, was developed. In order to improve determination of energy losses of the ³Не recoils in 20 μm silicon detectors, distributions of their thicknesses were measured with accuracy better than 0.2 μm (detailed review is in [3]). It allowed one to clearly identify all hydrogen, helium and lithium isotopes produced in ⁸He + d interactions by dE-E method with low threshold of ~1 MeV.

The feasibility of the ⁷Н studies in the ²Н(⁸Не,³Не)⁷Н reaction at the ACCULINNA-2 fragment separator was based on:

• methods of the triton energy and emission angle measurement in coincidence with ³Не and selection of true events related to ⁷Н (⁷Н → t + 4n) using the so called «kinematic triangle»;
• the use of the cryogenic deuterium gas target, providing high experimental resolution of ~ 1 MeV FWHM achieved in studies of the ⁷Н excitation spectrum, and well measured low background;
• possibility of calibration of applied missing mass method in reference reaction ²Н(¹⁰Bе,³Не)⁹Li performed at the same setup;
• high quality of RI beams at ACCULINNA-2 fragment separator (intensity, purity, focusing at physical target).

Taking advantage of the developed methods, a series of 3 experimental runs was carried out, and high quality data for the unknown ^6,7Н systems were acquired [6-8].

The second important measurements at ACCULINNA-2 were aimed at studies of low-lying states of ¹⁰Li system populated in the ⁹Li(d,p)¹⁰Li → n + ⁹Li reaction at 29 MeV per nucleon [4]. The key feature of this experiment was developed method of detection of proton, emitted at backward direction in laboratory system in coincidence with ⁹Li and neutrons emitted at forward angles. For precise measurement of neutron energy and their emission angle, specially designed array of 48 mono-crystal stilbene scintillator detectors [Bezbakh A.A. et al., Instrum. Exp. Tech., 2018 vol.61, No.5, p.631] was used. One of the important issues in detection of ⁹Li was the developed ToF detector consisted of thin plastic scintillator EJ-212 (125 μm) and four PMTs Hamamatsu R7600. This detector placed at distance of 39 cm downstream the physical target allowed one to identify the components of the secondary beam (d, ⁶He, ⁹Li и ¹²Be), and moreover, to separate incoming beam ⁹Li from one produced in the ¹⁰Li decay by dE-ToF method. To check the experimental resolution of the whole setup and normalization of the ¹⁰Li missing mass spectrum, the reference measurement of ⁶He(d,p)⁷He with triple coincidence p-⁶He-n was performed at the same setup. Based on the well-known properties of the ⁷Не ground state (E = 410 keV, Г = 150 keV), it was found, that the determination of the neutron energy on the 2 m base by time of flight provides the energy resolution of the reconstructed excitation spectrum of ~ 180 keV (FWHM). In addition, the angular analysis of the ⁷Не decay products at energies of 2-4 MeV showed the asymmetry in the emission angles of the reaction products with respect to the transferred momentum. This triple coincidence method was also applied in ⁹Не system studies, performed in ⁸He(d,p)⁹He reaction with a ⁸Не secondary beam at energy of 26 MeV/nucleon. Basing on the analysis of the collected data, it is expected to get new data on the structure of the studied systems.

New methods and experimental approaches, commissioned in the first experiments at the ACCULINNA-2 facility, provide the opportunity to observe new neutron-rich nuclei in the range 94 < Z < 107 with neutron-rich beams in multi-nucleon transfer reactions at threshold energy of 4-6 MeV per nucleon as well. This area is not available by means of other methods, though it is of special interest as a possible way to move towards the island of stability. Using the given methods, one can measure lifetime, fission barriers, and decay modes of such nuclei [5].

Development of experimental methods at ACCULINNA-2 coupled to U-400M facility offers new opportunities for resolving a number of tasks using RI beams with energies ~ 5÷50 MeV/nucleon: production and study of light nuclei (Z = 1÷16) lying beyond the boundaries of nucleon stability, investigation of rare decay modes, production of new isotopes of heavy elements (Z = 94÷107), and measurements of their fission barriers in the reactions of multi-nucleon transfers at the RI beams ⁹Li, ¹⁰Be, ^14,16C ^17,19N, ^20,22O, etc., up to ^24,26Ne.

1. A. S. Fomichev, A. A. Bezbakh, S. G. Belogurov, R. Wolski, E. M. Gazeeva, A. V. Gorshkov, L. V. Grigorenko, B. Zalewski, G. Kaminski, S. A. Krupko, I. A. Muzalevskii, E. Yu. Nikolskii, Yu. L. Parfenova, S. I. Sidorchuk, R. S. Slepnev, G. M. Ter-Akopian, V. Chudoba, and P. G. Sharov,
   “The first experiments with the new ACCULINNA-2 fragment separator”,
   Bulletin of the Russian Academy of Sciences: Physics, 83 (2019) 385–391.
2. G. Kaminski, B. Zalewski, S. G. Belogurov, A. A. Bezbakh, D. Biare, V. Chudoba, A. S. Fomichev, E. M. Gazeeva, M. S. Golovkov, A. V. Gorshkov, L. V. Grigorenko, D. A. Kostyleva, S. A. Krupko, I. A. Muzalevsky, E. Yu. Nikolskii, Yu. L. Parfenova, P. Plucinski, A. M. Quynh, A. Serikov, S. I. Sidorchuk, R. S. Slepnev, P. G. Sharov, P. Szymkiewicz, A. Swiercz, S. V. Stepantsov, G. M. Ter-Akopian, R. Wolski,
   “Status of the new fragment separator ACCULINNA-2 and first experiments”,
   Nucl. Instrum. Methods Phys. Res. B 463 (2020) 504-507.
3. I. A. Muzalevskii, V. Chudoba, S. G. Belogurov, A. A. Bezbakh, D. Biare, A. S. Fomichev, S. A. Krupko, E. M. Gazeeva, M. S. Golovkov, A. V. Gorshkov, L. V. Grigorenko, G. Kaminski, O. Kiselev, D. A. Kostyleva, M. Yu. Kozlov, B. Mauyey, I. Mukha, E. Yu. Nikolskii, Yu. L. Parfenova, W. Piatek, A. M. Quynh, V. N. Schetinin, A. Serikov, S. I. Sidorchuk, P. G. Sharov, R. S. Slepnev, S. V. Stepantsov, A. Swiercz, P. Szymkiewicz, G. M. Ter-Akopian, R. Wolski, B. Zalewski,
   “Detection of the low energy recoil 3He in the reaction ²H(⁸He,³He)⁷H”,
   Bulletin of the Russian Academy of Sciences: Physics, 84 (2020) 500-504.
4. A. A. Bezbakh, S. G. Belogurov, D. Biare, V. Chudoba, A. S. Fomichev, E. M. Gazeeva, M. S. Golovkov, A. V. Gorshkov, G. Kaminski, S. A. Krupko, B. Mauyey, I. A. Muzalevskii, E. Yu. Nikolskii, Yu. L. Parfenova, W. Piatek, A. M. Quynh, A. Serikov, S. I. Sidorchuk, P. G. Sharov, R. S. Slepnev, S. V. Stepantsov, A. Swiercz, P. Szymkiewicz, G. M. Ter-Akopian, R. Wolski, B. Zalewski, “Study of ¹⁰Li low energy spectrum in the ²H(⁹Li,p) reaction”,
   Bulletin of the Russian Academy of Sciences: Physics, 84 (2020) 491-494.
5. G. M. Ter-Akopian, Yu. Ts. Oganessian, A. A. Bezbakh, A. S. Fomichev, M. S. Golovkov, A. V. Gorshkov, S. A. Krupko, E. Yu. Nikolskii, S. I. Sidorchuk, S. V. Stepantsov, R. Wolski,
   “Radioactive-ion beams for the fission study of heavy neutron-rich nuclei”,
   Physics of Atomic Nuclei, 2020, Vol. 83, No. 4, 497–502.
6. A. A. Bezbakh, V. Chudoba, A. V. Gorshkov, S. A. Krupko, S. G. Belogurov, D. Biare, A. S. Fomichev, E. M. Gazeeva, L. V. Grigorenko, G.Kaminski, O. Kiselev, D. A. Kostyleva, I. Mukha, I. A. Muzalevskii, E. Yu. Nikolskii, Yu. L. Parfenova, A. M. Quynh, A. Serikov, S. I. Sidorchuk, P. G. Sharov, R. S. Slepnev, S. V. Stepantsov, A. Swiercz, P. Szymkiewicz, G. M. Ter-Akopian, R. Wolski, B. Zalewski, M. V. Zhukov,
   “Evidence for the first excited state of ⁷H”,
   Physical Review Letters 124 (2020) 022502.
7. I. A. Muzalevskii, A. A. Bezbakh, E. Yu. Nikolskii, V. Chudoba, S. A. Krupko, S. G. Belogurov, D. Biare, A. S. Fomichev, E. M. Gazeeva, A. V. Gorshkov, L. V. Grigorenko, G. Kaminski, O. Kiselev, D. A. Kostyleva, M. Yu. Kozlov, B. Mauyey, I. Mukha, Yu. L. Parfenova, W. Piatek, A. M. Quynh, V. N. Schetinin, A. Serikov, S. I. Sidorchuk, P. G. Sharov, N. B. Shulgina, R. S. Slepnev, S. V. Stepantsov, A. Swiercz, P. Szymkiewicz, G. M. Ter-Akopian, R. Wolski, B. Zalewski, M. V. Zhukov,
   “Resonant states in ⁷H: Experimental studies of the ²He(⁸He,³He) reaction”,
   Physical Review C 103 (2021) 044313.
8. E. Yu. Nikolskii, I. A. Muzalevskii, A. A. Bezbakh, V. Chudoba, S. A. Krupko, S. G. Belogurov, D. Biare, A. S. Fomichev, E. M. Gazeeva, A. V. Gorshkov, L. V. Grigorenko, G. Kaminski, O. Kiselev, D. A. Kostyleva, M. Yu. Kozlov, B. Mauyey, I. Mukha, Yu. L. Parfenova, W. Piatek, A. M. Quynh, V. N. Schetinin, A. Serikov, S. I. Sidorchuk, P. G. Sharov, N. B. Shulgina, R. S. Slepnev, S. V. Stepantsov, A. Swiercz, P. Szymkiewicz, G. M. Ter-Akopian, R. Wolski, B. Zalewski, M. V. Zhukov,
   “The ⁶H states studied in the ²He(⁸He,α) reaction and evidence of extremely correlated character of the ⁵H ground state”,
   Submitted to Physical Review C (2021) [arXiv:2105.04435].