The 6H states studied in the 2He(8He,4He) reaction and evidence of extremely correlated character of the 5H ground state

Abstract

The extremely neutron-rich system 6H was studied in the direct 2H(8He,4He)6H transfer reaction with a 26 A MeV secondary 8He beam. The measured missing mass spectrum shows a broad bump at 4-8 MeV above the 3H+3n decay threshold. This bump can be interpreted as a broad resonant state in 6H at 6.8(5) MeV. The population cross section of such a presumably p-wave state (or may be few overlapping states) in the energy range from 4 to 8 MeV is dσ/dc.m. 190+40-80 μb/sr in the angular range 5<θc.m.<16. The obtained missing mass spectrum is practically free of the 6H events below 3.5 MeV (dσ/dc.m. 5 μb/sr in the same angular range). The steep rise of the 6H missing mass spectrum at 3 MeV allows to derive the lower limit for the possible resonant-state energy in 6H to be 4.5(3) MeV. According to the paring energy estimates, such a 4.5(3) MeV resonance is a realistic candidate for the 6H ground state (g.s.). The obtained results confirm that the decay mechanism of the 7H g.s.\ (located at 2.2 MeV above the 3H+4n threshold) is the "true" (or simultaneous) 4n emission. The resonance energy profiles and the momentum distributions of fragments of the sequential 6H \,→ \, 5H(g.s.)+n\, → \, 3H+3n decay were analyzed by the theoretically-updated direct four-body-decay and sequential-emission mechanisms. The measured momentum distributions of the 3H fragments in the 6H rest frame indicate very strong "dineutron-type" correlations in the 5H ground state decay.