Triaxial dynamics in the quadrupole-deformed rotor

  • The triaxial dynamics of the quadrupole-deformed rotor model of both the rigid and the irrotational type are investigated in detail. The results indicate that level patterns of the two types of model can be matched with each other to the leading order of the deformation parameter β. In particular, it is found that the dynamical structure of the irrotational type with most triaxial deformation (γ=30°) is equivalent to that of the rigid type with oblate deformation (γ=60°), and the associated spectrum can be classified into the standard rotational bands obeying the rotational L(L+1)-law or regrouped into a new ground- and γ-band with odd-even staggering in the new γ-band, commonly recognized as a signature of the triaxiality. The differences between the two types of the model in this case are emphasized, especially in the E2 transitional characteristics.
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Qiu-Yue Li, Xiao-Xiang Wang, Yan Zuo, Yu Zhang and Feng Pan. Triaxial dynamics in the quadrupole-deformed rotor[J]. Chinese Physics C, 2016, 40(1): 014101. doi: 10.1088/1674-1137/40/1/014101
Qiu-Yue Li, Xiao-Xiang Wang, Yan Zuo, Yu Zhang and Feng Pan. Triaxial dynamics in the quadrupole-deformed rotor[J]. Chinese Physics C, 2016, 40(1): 014101.  doi: 10.1088/1674-1137/40/1/014101 shu
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Received: 2015-04-22
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    Supported by National Natural Science Foundation of China (11375005, 11005056, 11175078)

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Triaxial dynamics in the quadrupole-deformed rotor

    Corresponding author: Yu Zhang,
  • 1. Department of Physics, Liaoning Normal University, Dalian 116029, China
Fund Project:  Supported by National Natural Science Foundation of China (11375005, 11005056, 11175078)

Abstract: The triaxial dynamics of the quadrupole-deformed rotor model of both the rigid and the irrotational type are investigated in detail. The results indicate that level patterns of the two types of model can be matched with each other to the leading order of the deformation parameter β. In particular, it is found that the dynamical structure of the irrotational type with most triaxial deformation (γ=30°) is equivalent to that of the rigid type with oblate deformation (γ=60°), and the associated spectrum can be classified into the standard rotational bands obeying the rotational L(L+1)-law or regrouped into a new ground- and γ-band with odd-even staggering in the new γ-band, commonly recognized as a signature of the triaxiality. The differences between the two types of the model in this case are emphasized, especially in the E2 transitional characteristics.

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