Candidate chiral doublet bands in128La

“…However, for the Pr isotope chain, the doublet bands have been observed from 128 Pr to 134 Pr except for 130 Pr. Meanwhile, the doublet bands have also been observed in the 126 Cs [9] and 128 La [10], which are the isotones of 130 Pr. Hence, we infer that similar bands may appear in 130 Pr.…”

“…Previously, we have reported the positive-parity doublet bands with the configuration of πh 11/2 ⊗ νh 11/2 in 126 La [12] and 128 La [10] respectively. So far, the doublet bands have been systematically observed in odd-odd La isotopes from 124 La to 134 La.…”

“…In the A ∼ 130 mass region, the nearly degenerate ΔI = 1 doublet bands built on the πh 11/2 ⊗ νh 11/2 configuration have attracted significant attention and intensive discussion in odd-odd N = 77 ( 132 Cs, 134 La) [1,2], N = 75 ( 130 Cs, 132 La, 134 Pr, 136 Pm, 138 Eu) [3][4][5][6], N = 73 ( 128 Cs, 130 La, 132 Pr) [7,8], N = 71 ( 126 Cs, 128 La) [9,10], N = 69 ( 124 Cs, 126 La, 128 Pr) [11][12][13] and N = 67 ( 122 Cs, 124 La) [14,15] isotones. These ΔI = 1 doublet bands with the same positive parity are mostly interpreted as a manifestation of "chirality" in the sense of the angular momentum coupling [16].…”

Structure of a positive-parity band in 130Pr

“…However, for the Pr isotope chain, the doublet bands have been observed from 128 Pr to 134 Pr except for 130 Pr. Meanwhile, the doublet bands have also been observed in the 126 Cs [9] and 128 La [10], which are the isotones of 130 Pr. Hence, we infer that similar bands may appear in 130 Pr.…”

“…Previously, we have reported the positive-parity doublet bands with the configuration of πh 11/2 ⊗ νh 11/2 in 126 La [12] and 128 La [10] respectively. So far, the doublet bands have been systematically observed in odd-odd La isotopes from 124 La to 134 La.…”

“…In the A ∼ 130 mass region, the nearly degenerate ΔI = 1 doublet bands built on the πh 11/2 ⊗ νh 11/2 configuration have attracted significant attention and intensive discussion in odd-odd N = 77 ( 132 Cs, 134 La) [1,2], N = 75 ( 130 Cs, 132 La, 134 Pr, 136 Pm, 138 Eu) [3][4][5][6], N = 73 ( 128 Cs, 130 La, 132 Pr) [7,8], N = 71 ( 126 Cs, 128 La) [9,10], N = 69 ( 124 Cs, 126 La, 128 Pr) [11][12][13] and N = 67 ( 122 Cs, 124 La) [14,15] isotones. These ΔI = 1 doublet bands with the same positive parity are mostly interpreted as a manifestation of "chirality" in the sense of the angular momentum coupling [16].…”

Structure of a positive-parity band in 130Pr

“…Through this model both systems act as a thermal reservoir from which instantaneous spin and lattice temperatures can be extracted which can then be dynamically linked to the electron temperature thus representing a dynamic three temperature model. 61 Using this model, termed Spin-Lattice-Electron Dynamics (SLED) by Ma et al , experimental ultrafast laser induced magnetisation dynamics can be reproduced.…”

The Landau–Lifshitz equation in atomistic models

“…The TAPS collaboration carried out a series of comprehensive measurements studying in detail the properties of hard photons [49][50][51][52]. Theoretically, it was concluded that the neutron-proton bremsstrahlungs in the early stage of the reaction are the main source of high energy γ rays [53,54]. And it was demonstrated that the hard photons can be used to probe the reaction dynamics leading to the formation of dense matter [44,[55][56][57][58].…”

Constraining nucleon high momentum in nuclei