Title :
Polarizability of an optical lattice clock at 20 ppm
Author :
Sherman, Jeff A. ; Lemke, Nathan D. ; Hinkle, Nathan ; Fox, Richard W. ; Ludlow, Andrew D. ; Oates, Chris W.
Author_Institution :
Nat. Inst. of Stand. & Technol., Boulder, CO, USA
Abstract :
Optical lattice clocks, which are based on highly-forbidden 1S0 ↔ 3P0 transitions of ultracold alkaline-earth atoms confined in standing-wave optical potentials [1], offer exquisite frequency stability and uncertainty. We leverage these advantages to determine the sensitivity of a ytterbium optical lattice clock to external electric fields at 20 part-per-million (ppm) accuracy [2]. We describe an electrode design compatible with various neutral optical atomic clocks and capable of absolute electric field generation at the ppm level. Importantly, the result bounds the uncertainty of the ytterbium clock frequency due to room-temperature blackbody radiation at the level of 3×10-17.
Keywords :
atom-photon collisions; atomic clocks; blackbody radiation; laser frequency stability; laser transitions; measurement uncertainty; optical lattices; polarisability; radiation pressure; ytterbium; Yb; absolute electric field generation; electrode design; external electric fields; frequency stability; frequency uncertainty; highly-forbidden transitions; neutral optical atomic clocks; optical lattice clock; polarizability; room-temperature blackbody radiation; standing-wave optical potentials; temperature 293 K to 298 K; ultracold alkaline-earth atoms; ytterbium clock frequency; ytterbium optical lattice clock; Atom optics; Atomic clocks; Atomic measurements; Electrodes; Lattices; Optical variables measurement; Atomic measurements; Stark effect; blackbody radiation; clocks; electric fields; polarizability; precision measurements;
Conference_Titel :
Precision Electromagnetic Measurements (CPEM), 2012 Conference on
Conference_Location :
Washington, DC
Print_ISBN :
978-1-4673-0439-9
DOI :
10.1109/CPEM.2012.6250908
