A relativistic unitary coupled-cluster study of electric quadrupole moment and magnetic dipole hyperfine constants of 199Hg+

Abstract

Searching for an accurate optical clock which can serve as a better time standard than the present day atomic clock is highly demanding from several areas of science and technology. Several attempts have been made to built more accurate clocks with different ion species. In this article we discuss the electric quadrupole and hyperfine shifts in the 5d96s2 2D5/2(F=0,mF=0)5d106s 2S1/2(F=2,mF=0) clock transition in 199Hg+, one of the most promising candidates for next generation optical clocks. We have applied Fock-space unitary coupled-cluster (FSUCC) theory to study the electric quadrupole moment of the 5d96s2 2D5/2 state and magnetic dipole hyperfine constants of 5d96s2 2D3/2,5/2 and 5d106s1 2S1/2 states respectively of 199Hg+. We have also compared our results with available data. To the best of our knowledge, this is the first time a variant of coupled-cluster (CC) theories has been applied to study these kinds of properties of Hg+and is the most accurate estimate of these quantities to date.