Islands of shape coexistence from single-particle spectra in covariant density functional theory

Abstract: Shape coexistence in even-even nuclei is observed when the ground state band of a nucleus is accompanied by another K=0 band at similar energy but with radically different structure. We attempt to predict regions of shape coexistence throughout the nuclear chart using the parameter-free proxy-SU(3) symmetry and standard covariant density functional theory. Within the proxy-SU(3) symmetry the interplay of shell model magic numbers, formed by the spin-orbit interaction, and the 3-dimensional isotropic harmonic o… Show more

“…In particular (a) N = 90 signifies the beginning of participation of the intruder 1i 13/2 orbital. As seen in [10,11] The present findings further emphasize the difference between SC seen in the regions around Z = 82, 50 and in the regions around N = 90, 60. In the first set, SC is due to proton particle-hole (p-h) excitations caused by the neutrons (neutron-induced SC), while in the second set SC is due to neutron particle-hole excitations caused by the protons (protoninduced SC).…”

“…It has been accepted over the years that SC occurs when particle-hole (p-h) excitations across major shells are possible [1][2][3][4], the regions around Z = 82 and Z = 50 providing the most robust examples. Calculations of single-particle energy spectra using covariant density functional theory have recently corroborated this assumption, indicating that proton p-h excitations leading to SC occur in certain islands of the nuclear chart, centered around the Z = 82 and Z = 50 major shell gaps [10,11]. This has been called neutron-induced SC since they are caused by the varying number of neutrons acting on the same set of protons.…”

“…This has been called proton-induced SC, since they are caused by the varying in number protons acting on the same set of neutrons. In addition, a region around N = 40, Z = 40 has been found, in which both proton p-h excitations and neutron p-h excitations are possible [11].…”

“…This has been called neutron-induced SC since they are caused by the varying number of neutrons acting on the same set of protons. Furthermore, it has been suggested that islands of SC occurring around N = 90 and N = 60 can be attributed to neutron p-h excitations across the N = 112 and N = 70 shell closures of the three-dimensional isotropic harmonic oscillator (3D-HO), signifying the beginning of the participation of the intruder (opposite parity) orbitals 1i 13/2 and 1h 11/2 to the onset of nuclear deformation [10,11]. This has been called proton-induced SC, since they are caused by the varying in number protons acting on the same set of neutrons.…”

Signatures for shape coexistence and shape/phase transitions in even–even nuclei

“…In particular (a) N = 90 signifies the beginning of participation of the intruder 1i 13/2 orbital. As seen in [10,11] The present findings further emphasize the difference between SC seen in the regions around Z = 82, 50 and in the regions around N = 90, 60. In the first set, SC is due to proton particle-hole (p-h) excitations caused by the neutrons (neutron-induced SC), while in the second set SC is due to neutron particle-hole excitations caused by the protons (protoninduced SC).…”

“…It has been accepted over the years that SC occurs when particle-hole (p-h) excitations across major shells are possible [1][2][3][4], the regions around Z = 82 and Z = 50 providing the most robust examples. Calculations of single-particle energy spectra using covariant density functional theory have recently corroborated this assumption, indicating that proton p-h excitations leading to SC occur in certain islands of the nuclear chart, centered around the Z = 82 and Z = 50 major shell gaps [10,11]. This has been called neutron-induced SC since they are caused by the varying number of neutrons acting on the same set of protons.…”

“…This has been called proton-induced SC, since they are caused by the varying in number protons acting on the same set of neutrons. In addition, a region around N = 40, Z = 40 has been found, in which both proton p-h excitations and neutron p-h excitations are possible [11].…”

“…This has been called neutron-induced SC since they are caused by the varying number of neutrons acting on the same set of protons. Furthermore, it has been suggested that islands of SC occurring around N = 90 and N = 60 can be attributed to neutron p-h excitations across the N = 112 and N = 70 shell closures of the three-dimensional isotropic harmonic oscillator (3D-HO), signifying the beginning of the participation of the intruder (opposite parity) orbitals 1i 13/2 and 1h 11/2 to the onset of nuclear deformation [10,11]. This has been called proton-induced SC, since they are caused by the varying in number protons acting on the same set of neutrons.…”

Signatures for shape coexistence and shape/phase transitions in even–even nuclei

“…A by-product of proxy-SU(3) symmetry and the dominance of the highest weight irreps is the resolution [60,104,191,199] of the long standing problem of the dominance of prolate over oblate shapes [17,18] in the ground states of even-even nuclei. Another by-product of the proxy-SU(3) symmetry is the dual shell mechanism [200], which predicts that shape coexistence can occur only on specific islands of the nuclear chart [77,201,202], recently corroborated through CDFT calculations [203,204].…”

Prolate-oblate shape transitions and O(6) symmetry in even–even nuclei: a theoretical overview

Relation between degrees of collectivity and repetition patterns of quadrupole transition probabilities in the candidates of shape coexistence