An Optimized Ion Trap Geometry to Measure Quadrupole Shifts of 171Yb+ Clocks

Abstract

We propose a new ion-trap geometry to carry out accurate measurements of the quadrupole shifts in the 171Yb-ion. This trap will produce nearly ideal harmonic potential where the quadrupole shifts due to the anharmonic components can be reduced by four orders of magnitude. This will be useful to reduce the uncertainties in the clock frequency measurements of the 6s~2S1/2 → 4f13 6s2 ~2F7/2 and 6s~2S1/2 → 5d ~2D3/2 transitions, from which we can deduce precise values of the quadrupole moments () of the 4f13 6s2 ~2F7/2 and 5d ~2D3/2 states. Moreover, it may be able to affirm validity of the measured value of the 4f13 6s2 ~2F7/2 state where three independent theoretical studies defer almost by one order in magnitude from the measurement. We also perform calculations of using the relativistic coupled-cluster (RCC) method. We use these values to estimate quadrupole shift that can be measured in our proposed ion trap experiment.