Lifetime-Limited Interrogation of Two Independent 27Al+ Clocks Using Correlation Spectroscopy

Lifetime-Limited Interrogation of Two Independent 27Al+ Clocks Using Correlation Spectroscopy

Laser decoherence limits the stability of optical clocks by broadening the observable resonance linewidths and adding noise during the dead time between clock probes. Correlation spectroscopy avoids these limitations by measuring correlated atomic transitions between two ensembles, which provides a...

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Bibliographic Details
Published in:Physical review letters Vol. 125; no. 24; pp. 1 - 243602
Main Authors: Clements, Ethan R, Kim, May E, Cui, Kaifeng, Hankin, Aaron M, Brewer, Samuel M, Valencia, Jose, Chen, Jwo-Sy, Chou, Chin-Wen, Leibrandt, David R, Hume, David B
Format: Journal Article
Language:English
Published: College Park American Physical Society 11-12-2020
American Physical Society (APS)
Subjects:
ATOMIC AND MOLECULAR PHYSICS
Atomic, optical & lattice clocks
Clocks
Correlation analysis
Interrogation
Laser spectroscopy
Noise
Noise measurement
Optical coherence
Quantum correlations in quantum information
Quantum measurements
Quantum metrology
Spectrum analysis
Stability
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Summary:Laser decoherence limits the stability of optical clocks by broadening the observable resonance linewidths and adding noise during the dead time between clock probes. Correlation spectroscopy avoids these limitations by measuring correlated atomic transitions between two ensembles, which provides a frequency difference measurement independent of laser noise. Here, we apply this technique to perform stability measurements between two independent clocks based on the 1S0 ↔ 3P0 transition in 27Al+. By stabilizing the dominant sources of differential phase noise between the two clocks, we observe coherence between them during synchronous Ramsey interrogations as long as 8 s at a frequency of 1.12×1015 Hz. The observed contrast in the correlation spectroscopy signal is consistent with the 20.6 s 3P0 state lifetime and represents a measurement instability of (1.8±0.5)×10−16/√τ/s for averaging periods longer than the probe duration when dead time is negligible.
Bibliography:AC02-06CH11357
USDOE
Present address: Colorado State University, Fort Collins, Colorado 80523, USA.
Present address: Honeywell Quantum Solutions, Broom-field, Colorado 80021, USA.
Present address: IonQ Inc., College Park, Maryland 20740, USA.
ISSN:0031-9007
1079-7114
DOI:10.1103/PhysRevLett.125.243602