Sebastian Blatt scite author profile

Optical atomic clocks promise timekeeping at the highest precision and accuracy, owing to their high operating frequencies. Rigorous evaluations of these clocks require direct comparisons between them. We have realized a high-performance remote comparison of optical clocks over kilometer-scale urban distances, a key step for development, dissemination, and application of these optical standards. Through this remote comparison and a proper design of lattice-confined neutral atoms for clock operation, we evaluate the uncertainty of a strontium (Sr) optical lattice clock at the 1 × 10 –16 fractional level, surpassing the current best evaluations of cesium (Cs) primary standards. We also report on the observation of density-dependent effects in the spin-polarized fermionic sample and discuss the current limiting effect of blackbody radiation–induced frequency shifts.

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Site-Resolved Imaging of FermionicLi6in an Optical Lattice

Parsons¹,

Huber²,

Mazurenko³

et al. 2015

Phys. Rev. Lett.

330

355

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We demonstrate site-resolved imaging of individual fermionic 6 Li atoms in a 2D optical lattice. To preserve the density distribution during fluorescence imaging, we simultaneously cool the atoms with 3D Raman sideband cooling. This laser cooling technique, demonstrated here for the first time for 6 Li atoms, also provides a pathway to rapid low-entropy filling of an optical lattice. We are able to determine the occupation of individual lattice sites with a fidelity >95%, enabling direct, local measurement of particle correlations in Fermi lattice systems. This ability will be instrumental for creating and investigating low-temperature phases of the Fermi-Hubbard model, including antiferromagnets and d-wave superfluidity.

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Compact, thermal-noise-limited optical cavity for diode laser stabilization at 1×10^−15

et al. 2007

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We demonstrate phase and frequency stabilization of a diode laser at the thermal noise limit of a passive optical cavity. The system is compact and exploits a cavity design that reduces vibration sensitivity. The sub-Hz laser is characterized by comparison to a second independent system with similar fractional frequency stability (1 x 10 -15 at 1 s). The laser is further characterized by resolving a 2 Hz wide, ultranarrow optical clock transition in ultracold strontium.

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New Limits on Coupling of Fundamental Constants to Gravity UsingSr87Optical Lattice Clocks

et al. 2008

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The 1S0-3P0 clock transition frequency nuSr in neutral 87Sr has been measured relative to the Cs standard by three independent laboratories in Boulder, Paris, and Tokyo over the last three years. The agreement on the 1 x 10(-15) level makes nuSr the best agreed-upon optical atomic frequency. We combine periodic variations in the 87Sr clock frequency with 199Hg+ and H-maser data to test local position invariance by obtaining the strongest limits to date on gravitational-coupling coefficients for the fine-structure constant alpha, electron-proton mass ratio mu, and light quark mass. Furthermore, after 199Hg+, 171Yb+, and H, we add 87Sr as the fourth optical atomic clock species to enhance constraints on yearly drifts of alpha and mu.

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Sebastian Blatt

Sr Lattice Clock at 1 × 10 ^–16 Fractional Uncertainty by Remote Optical Evaluation with a Ca Clock

Site-Resolved Imaging of FermionicLi6in an Optical Lattice

Compact, thermal-noise-limited optical cavity for diode laser stabilization at 1×10^−15

New Limits on Coupling of Fundamental Constants to Gravity UsingSr87Optical Lattice Clocks

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Resources

About

Sebastian Blatt

Sr Lattice Clock at 1 × 10 –16 Fractional Uncertainty by Remote Optical Evaluation with a Ca Clock

Site-Resolved Imaging of FermionicLi6in an Optical Lattice

Compact, thermal-noise-limited optical cavity for diode laser stabilization at 1×10^−15

New Limits on Coupling of Fundamental Constants to Gravity UsingSr87Optical Lattice Clocks

Contact Info

Product

Resources

About

Sr Lattice Clock at 1 × 10 ^–16 Fractional Uncertainty by Remote Optical Evaluation with a Ca Clock