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Shape evolution in heaviest stable even-even molybdenum isotopes studied via coulomb excitation

Wrzosek-Lipska, K.*; Zieli$'n$ska, M.*; Hady$'n$ska-Klek, K.*; Hatsukawa, Yuichi; Iwanicki, J.*; Katakura, Junichi; Kisieli$'n$ski, M.*; Koizumi, Mitsuo; Kowalczyk, M.*; Kusakari, Hideshige*; Matsuda, Makoto; Morikawa, Tsuneyasu*; Napiorkowski, P. J.*; Osa, Akihiko; Oshima, Masumi; Pi$c{e}$tak, D.*; Pr$'o$chniak, L.*; Shizuma, Toshiyuki; Srebrny, J.*; Sugawara, Masahiko*; Toh, Yosuke 

The quadrupole shape evolution in heaviest stable Mo isotopes is studied in terms of the shape coexistence phenomenon occurrence in this region of nuclear chart. Quadrupole deformation parameters of the $$^{96,98,100}$$Mo isotopes in the low-lying (ground and excited) 0$$^+$$ states were deduced using Coulomb excitation method. In all cases rich sets of electromagnetic reduced matrix elements were determined using the GOSIA code and then analyzed using the Quadrupole Sum Rules formalism. Discussion of the experimental results in comparison with the predictions of microscopic calculations within the general quadrupole collective Bohr Hamiltonian model is presented for $$^{100}$$Mo.



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Category:Physics, Nuclear



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