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Determination of hexadecapole (β₄) deformation of the light-mass nucleus ²⁴Mg using quasi-elastic measurement

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arxiv 1811.12756 v3 pith:MUE43ER6 submitted 2018-11-30 nucl-ex nucl-th

Determination of hexadecapole (β₄) deformation of the light-mass nucleus ²⁴Mg using quasi-elastic measurement

classification nucl-ex nucl-th
keywords betaquasi-elasticscatteringbeendeformationbarriercalculationscoupling
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Quasi-elastic scattering measurements have been performed using $^{16}$O and $^{24}$Mg projectiles off $^{90}$Zr at energies around the Coulomb barrier. Experimental data have been analyzed in the framework of coupled channels (CC) calculations using the code CCFULL. The quasi-elastic scattering excitation function and derived barrier distribution for $^{16}$O + $^{90}$Zr reaction are well reproduced by the CC calculations using the vibrational coupling strengths for $^{90}$Zr reported in the literature. Using these vibrational coupling strengths, a Bayesian analysis is carried out for $^{24}$Mg + $^{90}$Zr reaction. The $\beta_{2}$ and $\beta_{4}$ values for $^{24}$Mg are determined to be $+0.43 \pm 0.02$ and $ - 0.11 \pm 0.02$, respectively. The $\beta_{2}$ parameter determined in the present work is in good agreement with results obtained using inelastic scattering probes. The hexadecapole deformation of $^{24}$Mg has been measured very precisely for the first time. Present results establish that quasi-elastic scattering could provide a useful probe to determine the ground state deformation of atomic nuclei.

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