6533b823fe1ef96bd127f430

RESEARCH PRODUCT

Mirror symmetry at high spin in51Feand51Mn

W. GelletlyP. ReiterSm VincentS.j. WilliamsD. SeweryniakD. T. JossP. H. ReganP. FallonC. J. ListerGabriel Martínez-pinedoM. P. CarpenterC. E. SvenssonL. FranklandM. A. BentleyJ. Sanchez SolanoAlison BruceC.d. O'learyD. D. WarnerAlfredo PovesB. RubioJ. A. Cameron

subject

PhysicsNuclear and High Energy PhysicsExcited stateElectric potential energyGamma rayCoulombAtomic physicsMirror symmetrySymmetry (physics)ExcitationSpin-½

description

Gamma decays from excited states in the ${T}_{z}=\ensuremath{-}\frac{1}{2}$ nucleus ${}^{51}$Fe have been observed for the first time. The differences in excitation energies as compared with those of the mirror partner, ${}^{51}$Mn, have been interpreted in terms of Coulomb effects and the resulting Coulomb energy differences (CED) can be understood intuitively in terms of particle-alignment effects. A new CED effect has been observed, in which different CED trends have been measured for each signature of the rotational structures that characterize these mid-${f}_{7/2}$ shell nuclei. Large-scale $\mathrm{fp}$-shell model calculations have been used to compute the trends of the CED as a function of spin. The result of comparing these calculations with the data demonstrates an ability to reproduce the fine details of the Coulomb effects with a precision far greater than has been previously achieved.

yearjournalcountryeditionlanguage
2000-10-17Physical Review C
https://doi.org/10.1103/physrevc.62.051303