TY - JOUR KW - Atomic Physics (physics.atom-ph) KW - Quantum Gases (cond-mat.quant-gas) KW - FOS: Physical sciences KW - FOS: Physical sciences AU - William Milner AU - L. Yan AU - Ross Hutson AU - Christian Sanner AU - Jun Ye AB -
We report on the observation of a high-density, band insulating state in a three-dimensional optical lattice clock. Filled with a nuclear-spin polarized degenerate Fermi gas of 87Sr, the 3D lattice has one atom per site in the ground motional state, thus guarding against frequency shifts due to contact interactions. At this high density where the average distance between atoms is comparable to the probe wavelength, standard imaging techniques suffer from large systematic errors. To spatially probe frequency shifts in the clock and measure thermodynamic properties of this system, accurate imaging techniques at high optical depths are required. Using a combination of highly saturated fluorescence and absorption imaging, we confirm the density distribution in our 3D optical lattice in agreement with a single spin band insulating state. Combining our clock platform with this high filling fraction opens the door to studying new classes of long-lived, many-body states arising from dipolar interactions.
BT - Physical Review A DA - 2023-06 DO - 10.1103/PhysRevA.107.063313 N1 - Submitted: 20230109 N2 -We report on the observation of a high-density, band insulating state in a three-dimensional optical lattice clock. Filled with a nuclear-spin polarized degenerate Fermi gas of 87Sr, the 3D lattice has one atom per site in the ground motional state, thus guarding against frequency shifts due to contact interactions. At this high density where the average distance between atoms is comparable to the probe wavelength, standard imaging techniques suffer from large systematic errors. To spatially probe frequency shifts in the clock and measure thermodynamic properties of this system, accurate imaging techniques at high optical depths are required. Using a combination of highly saturated fluorescence and absorption imaging, we confirm the density distribution in our 3D optical lattice in agreement with a single spin band insulating state. Combining our clock platform with this high filling fraction opens the door to studying new classes of long-lived, many-body states arising from dipolar interactions.
PB - arXiv PY - 2023 EP - 063313 T2 - Physical Review A TI - High-fidelity imaging of a band insulator in a three-dimensional optical lattice clock UR - https://journals.aps.org/pra/abstract/10.1103/PhysRevA.107.063313 VL - 107 ER -