First spectroscopy of 61Ti and the transition to the Island of Inversion at N = 40

Isomeric states in 59,61Ti have been populated in the projectile fragmentation of a 345 AMeV 238U beam at the Radioactive Isotope Beam Factory. The decay lifetimes and delayed gamma-ray transitions were measured with the EURICA array. Besides the known isomeric state in 59Ti, two isomeric states in 61Ti are observed for the first time. Based on the measured lifetimes, transition multipolarities as well as tentative spins and parities are assigned. Large-scale shell model calculations based on the modified LNPS interaction show that both 59Ti and 61Ti belong to the Island of Inversion at N=40 with ground state configurations dominated by particle-hole excitations to the g_9/2 and d_5/2 orbits.


Introduction
The study of nuclei far off stability in regions that have not yet been explored -and in particular its description in terms of nuclear shell structure -is fundamental in order to obtain predictive capabilities and to be able to understand the relevant characteristics of such nuclei. Due to enormous computational advancements in the recent years and the development of new interactions, the shell model is now able to predict the structure of nuclei far from closed shells. One example of this are the neutron-rich N = 40 nuclei below 68 Ni ( Z = 28). Although the energy and the B(E2) value of the first 2 + 1 state of 68 Ni suggest a shell closure, the neutron separation energies show a smooth trend across N = 40 [1]. By removing a few protons, a rapid increase of collectivity has been observed in the Fe and Cr isotopes, suggesting a weakening of the N = 40 sub-shell closure [2,3].
This collective behavior is caused by quadrupole correlations which energetically favor the deformed intruder states involving the neutron 1g 9/2 and 2d 5/2 orbitals and proton excitations across the Z = 28 sub-shell gap. Moreover, the imbalance between protons and neutrons modifies the shell structure in this region. These changes in the intrinsic shell structure are of fundamental interest for testing the validity of modern interactions and their predictive power farther from stability. The subtle interplay between such shell-evolution mechanisms provokes the modification of the magic numbers and gives rise to new regions of deformation and shape coexistence phenomena. Previous studies indicate 64 Cr is the center of a new region of prolate deformation. As in the case of 32 Mg at N = 20, shape coexistence should be expected in this region [4].
The region of neutron-rich nuclei around N = 40 is also characterized by the occurrence of long-lived excited states in these nuclei. The large difference in angular momentum between the ν2p 1/2 , 1 f 5/2 and 2d 5/2 , 1g 9/2 orbitals around the Fermi surface in N ∼ 40 nuclei leads to the occurrence of isomeric states. These isomeric states are well established along the Ni and Fe isotopic chains [5][6][7]. Farther below in the Cr and Ti isotopes, such isomers should also exist. In 59 Ti an isomeric state with a half-life of 590 ns was discovered [8]. Based on Weisskopf estimates, an E2 transition connecting the 5/2 − and 1/2 − states was proposed. A positive parity isomeric state based on the ν g 9/2 intruder configuration is also expected. The location of such pure configurations in the most neutron-rich nuclei is paramount to test the predictions of shell model calculations for the most exotic N = 40 nuclei 60 Ca and 59 K which are still beyond the reach of presently available radioactive beam facilities for spectroscopic studies. First experimental hints have been obtained from the first spectroscopy of 60 Ti [9] and the discovery of particle-bound 60 Ca [10].
In this letter, we present a search for new isomers in 59 Ti and report on the first spectroscopic study of 61 Ti. The experimental results are interpreted in terms of neutron holes for the N = 39 nuclei and as excitations across the weak N = 40 sub-shell closure.
The excitation energies of these simple configurations provide direct insight in the structure, in an even more interesting and direct way than from the spectroscopy of the neighboring even-even nuclei.

Experimental setup
The experiment was performed at Radioactive Isotope Beam Factory (RIBF), operated by RIKEN Nishina Center and CNS, Uni- versity of Tokyo. A wide range of exotic neutron-rich nuclei were produced by fragmentation of a 238 U at 345 AMeV on a Be primary target (thickness 4 mm) at the entrance of the BigRIPS fragment separator [11]. An average primary beam intensity of 23 pnA was achieved. In order to purify the beam, two wedge-shaped degraders with central thickness of 6 and 2.5 mm were located at the dispersive F1 and F5 focal planes of BigRIPS. Fragments were identified in Z and A/q by measuring the energy loss ( E), time-of-flight (T O F ), and the magnetic rigidity (Bρ) in BigRIPS ( E − T O F − Bρ method) and then transported to the experimental setup at the final F11 focal point of the ZeroDegree spectrometer. Data were taken in two settings, centered on 64 V and 60 Ti, respectively. The particle identification plots are shown in Fig. 1. The nuclei were then further degraded in energy and implanted in the Advanced Implantation Detector Array (AIDA) [12]. The present experimental results are part of a β-decay experiment whose results will be presented in a forthcoming publication [13]. Here, we only concentrate on the decay of isomeric states, and thus AIDA served as a passive stopper. The array was surrounded by the highpurity Ge EUroball RIKEN Cluster Array (EURICA) [14], consisting of 84 Ge crystals with an efficiency of about 10% at 1332 keV. Data were recorded independently by the BigRIPS, AIDA, and EURICA data acquisition systems, and correlated off-line by means of their synchronized time-stamps. This allowed for the analysis of short (∼ μs lifetime) and long lived isomeric decays, as well as β decays.

Isomeric decay of 59 Ti
The isomeric decay of 59 Ti was studied previously at RIBF [8].
In the present study, a factor of ∼20 times more statistics was obtained. The delayed coincidence γ -ray energy spectrum is shown in Fig. 2. One transition at 108.5(5) keV was observed. The lifetime of the isomer was obtained from a decay curve fit to the γ -ray detection time after the implantation. The resulting lifetime is τ = 892 (18) ns. This value is in agreement with the previous measurement [8], but more precise due to the improved statistics. No other delayed transition in 59 Ti has been observed based on the comparison with the neighboring isotopes. The background is well reproduced by scaling the corresponding spectrum for 61 V with no known isomeric state for the number of implanted ions.
Previous β-decay experiments [15,16] suggested a spin and parity of J π = 5/2 − for the ground state of 57 Ti based on systematics and comparison with shell model calculations using the GXPF1 interaction [17]. These calculations predict the first excited state with J π = 1/2 − at 422 keV. Experimentally the first excited state is located at 364 keV [16] and J π = 1/2 − was assigned. However, the strong feeding of the excited state in the β decay of the J π = 7/2 − ground state of 57 Sc would suggest a reversed ordering. For 59 Ti, J π = (5/2 − ) was assigned to the ground state as well [8] based on systematics, and (1/2 − ) was proposed for the isomer. In the present work, using a total conversion coefficient α = 0.249 [18], the transition probability for an E2 transition with τ = 892(18) ns amounts to B(E2) = 48.8(10) e 2 fm 4 or 3.58(7) W.u. Other assumptions for the multipolarity result in unreasonable transition probabilities. The excited state is assigned as J π = (1/2 − ), if the ground state is 5/2 − . From the present experimental data, it can not be excluded that the 108.5 keV E2 transition may originate from the decay of positive parity 9/2 + or 5/2 + states. In the 63,65 Fe nuclei the 9/2 + states are β-decaying isomers, thus longer correlation times (up to 10 ms) between the implantation of 59 Ti and subsequent detection of γ rays were investigated. No other isomeric transition was found, in particular none in coincidence with the 108 keV transition. This indicates that the 108 keV tran- sition is originating from the only γ -decaying isomer in 59 Ti and that it is a ground-state transition. If isomeric, other states like the positive parity 9/2 + or 5/2 + states could decay by β emission. The β decay of 59 Ti was investigated and the resulting lifetime is in agreement with previous work [19] with only one β-decaying state.

First spectroscopy of 61 Ti
In 61 Ti two delayed transitions at 125.0(5) and 575.1(5) keV were observed. The γ -ray energy spectrum is shown in Fig. 3. γ − γ coincidences show that the two transitions originate from a cascade decay of a level at 700 keV. Based on the intensity and the lifetimes (see below) the existence of two isomeric states in 61 Ti are suggested, both with approximately equal ratios in the beam at the implantation position. The level at 700 keV decays to the 125 keV state by the 575 keV transition; however, indirect feeding of the 125 keV state alone does not explain the number of counts observed in the spectrum in Fig. 3. The full-energy peak detection efficiency of EURICA in the present configuration amounts to ≈ 12% at 575 keV and ≈ 25% at 125 keV, while about four times as many counts are observed in the 125 keV transition in Fig. 3. To corroborate this assumption, the lifetimes of the two states were determined in Fig. 4 The parity of the 700 keV state is thus positive. This fixes the spin and parity of the 700 keV state to be J π = 9/2 + and the one of the lower isomer at 125 keV to be J π = 5/2 − (otherwise decay to the ground state would be more probable). The ground state is then assigned J π = (1/2 − ) based on the E2 transition. The suggested level scheme is shown in the inset of Fig. 3.
This result also puts a constraint on the location of the 5/2 + state in 61 Ti. Assuming 1 W.u. for the transition of the 9/2 + state to the 5/2 + state and a partial lifetime that is 10 times longer than the τ (M2; 9/2 + → 5/2 − ) measured here, such that the de- cay is not observable, the 5/2 + state can only be located 96 keV below the 9/2 + state or at any energy higher. For less conservative assumptions, the limit is more stringent.

Discussion
The present data have been interpreted in the framework of the large-scale shell model calculations using the LNPS interaction [4]. The model space consists of the full pf shell for protons and the 1 f 5/2 , 2p 3/2 , 2p 1/2 , 1g 9/2 , and 2d 5/2 neutron orbitals outside a 48 Ca core. The results are shown in Fig. 5 in comparison with the present data. Calculations with the same interaction but limited to the full pf shell for both protons and neutrons, i.e. using a 40 Ca core and not allowing excitations to the gd orbits, are denoted as LNPS-fp. The calculations for 61 Ti in the large model space accurately reproduce the data. The ground state is predicted to be J π = 1/2 − , with an excited first 5/2 − state at 185 keV. Using the effective charges e π = 1.31 and e ν = 0.46 [20], the calculated transition probability for the decay to the ground state is B(E2; 5/2 − → 1/2 − ) = 60 e 2 fm 4 , compatible with 81(10) e 2 fm 4 determined from the measured lifetime. The wave functions are dominated by ν( f p) −5 (gd) 4 configurations. The clear intruder dominance in the ground state shows that 61 Ti belongs to the Island of Inversion. Regarding the positive parity states, the lowest state is a 5/2 + state at 591 keV, while the 9/2 + state, lying just 47 keV above it, becomes isomeric. The calculations are compatible with the data and therefore J π = (1/2 − ) is assigned to the ground state, J π = (5/2 − ) to the first state at 125 keV, and J π = (9/2 + ) to the 700-keV isomeric state in 61 Ti. A very differ- the level scheme shown in Fig. 5 (b) is incompatible with the experimental findings. Based on the good agreement of the calculations with the LNPS interaction with the data we propose to assign J π = (1/2 − ) to the ground state and J π = (5/2 − ) to the isomer in 59 Ti. The first 9/2 + state is predicted at 500 keV and the 5/2 + state is located 230 keV above it at 730 keV. This suggests a 9/2 + isomeric state. Since it is located below the 5/2 + state, it can only decay via a M2 transition to the first excited state. Experimentally only one isomer has been observed in the present work. However, as stated above, the possibility of another longlived state can not be ruled out. If the lifetime of such a state is significantly shorter than the flight time through the separator, or it is a γ -decaying isomer with a lifetime longer than ∼ 10 ms, or if such an isomer was not populated in the fragmentation reaction, it would not have been observed in the present experiment.
It is interesting to explore the evolution of the structure in the lighter Ti isotopes to investigate the boundaries of the Island of Inversion along the isotopic chain. In 57 Ti at N = 35, only two states with suggested negative parity are known experimentally [16].
Originally the ground state had been assigned J π = 5/2 − with an excited 1/2 − state based on comparison with the GXPF1 interaction [17]. On the contrary, as shown in Fig. 5 (c), the calculations with the LNPS interaction in both model spaces predict a ground state with J π = 1/2 − and a first excited 5/2 − state. This spin sequence also agrees with the observed large feeding in the β decay of the J π = 7/2 − ground state of 57 Sc to the excited state at 364 keV in 57 Ti. This suggests a change of the spin assignments proposed in 5 (c). The ground state of 57 Ti is dominated in the LNPS calculations by f p configurations, with marginal excitations to the gd orbitals, which locates therefore N = 35 57 Ti outside the N = 40 Island of Inversion. Similar conclusions can be drawn for 55 Ti.
The success in describing the data for these heavy Ti isotopes is encouraging for predictions above the N = 40 sub-shell closure. For 63 Ti a similar spectrum as in 61 Ti is expected with the 5/2 − state at 76 keV excitation energy and the 3/2 − state at 140 keV, while the 7/2 − remains higher in energy at 620 keV. The positive-parity states suggest the occurrence of only one isomeric state in this nucleus. At N = 40 and removing two protons, 60 Ca is predicted to have ground, 2 + and 4 + yrast states with dominant 4p − 4h neutron excitations into the 1g 9/2 and 2d 5/2 orbits [4]. Looking at the N = 39 isotones from Ni to Ca, the calculations predict 0p − 0h excitations into the gd orbitals for the ground state of 67 Ni, 2p − 2h for 65 Fe, and 4p − 4h for 63 Cr, 61 Ti and 59 Ca. In determining the collectivity and B(E2) values, the proton configurations play a major role. As for the N = 40 isotones [4], maximum collectivity is obtained mid-shell for 63 Cr, with a decreasing trend towards Z = 20.
In summary, first spectroscopic information of 61 Ti has been obtained through isomeric spectroscopy. Two states were observed, suggesting two isomeric states, a 9/2 + state at 700 keV and a 5/2 − state at 125 keV. The lifetimes were measured and from comparison to Weisskopf estimates the transition multipolarities and thus spin and parity assignments were made. Candidates for positive parity states in 59 Ti were not observed, but they might have been out of the reach of the present experiment. The results suggest that particle-hole excitations across the N = 40 sub-shell closure play a major role in the wave function of the low-lying states of neutron-rich Ti isotopes. Both 59 Ti and 61 Ti belong to the Island of Inversion around N = 40.