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Coherent suppression of tensor frequency shifts through magnetic field rotation

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arxiv 2005.14687 v1 pith:XMR2ZHRY submitted 2020-05-29 physics.atom-ph quant-ph

Coherent suppression of tensor frequency shifts through magnetic field rotation

classification physics.atom-ph quant-ph
keywords frequencyatomicelectricquadrupoletransitionfieldmagneticmagnitude
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We introduce a scheme to coherently suppress second-rank tensor frequency shifts in atomic clocks, relying on the continuous rotation of an external magnetic field during the free atomic state evolution in a Ramsey sequence. The method retrieves the unperturbed frequency within a single interrogation cycle and is readily applicable to various atomic clock systems. For the frequency shift due to the electric quadrupole interaction, we experimentally demonstrate suppression by more than two orders of magnitude for the ${}^2S_{1/2} \to {}^2D_{3/2}$ transition of a single trapped ${}^{171}\text{Yb}^+$ ion. The scheme provides particular advantages in the case of the ${}^{171}\text{Yb}^+$ ${}^2S_{1/2} \to {}^2F_{7/2}$ electric octupole (E3) transition. For an improved estimate of the residual quadrupole shift for this transition, we measure the excited state electric quadrupole moments $\Theta({}^2D_{3/2}) = 1.95(1)~ea_0^2$ and $\Theta({}^2F_{7/2}) = -0.0297(5)~ea_0^2$ with $e$ the elementary charge and $a_0$ the Bohr radius, improving the measurement uncertainties by one order of magnitude.

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