Measurement of the Differential Static Scalar Polarizability of the 88Sr+ Clock Transition

Abstract

We report on a precision measurement of the differential static scalar polarizability α0 of the 2\!S1/2 → 2\!D5/2 optical clock transition in the 88Sr+ ion. The polarizability was determined from the 'magic' ion-trap drive frequency where the micromotion-induced second-order Doppler and quadratic Stark shifts cancel, using a single clock in an interleaved scheme by switching between minimized and large micromotion. By measuring at different Mathieu qz parameters, α0 can be obtained without prior knowledge of the angle between the rf electric field and the trap axis, which would otherwise dominate the systematic uncertainty. For validation, measurements were carried out at different micromotion levels and by displacing the ion in opposite directions. The results show excellent consistency and our value, α0 = -4.8314(20)× 10-40\;J\, m2/V2 = -29.303(12)\;au, reduces the uncertainty by a factor of 3.5 compared to a previous measurement, while showing a discrepancy of 5 σ. Our measurement reduces the polarizability-related uncertainty of the 88Sr+ clock to 2.2× 10-19 for a blackbody radiation temperature of 295 K -- a significant step towards total uncertainties <1×10-18. Using existing polarizability transfer schemes, the result can reduce the uncertainty also for other ion species.