High-dynamic-range atomic clocks with dual Heisenberg-limited precision scaling
- URL: http://arxiv.org/abs/2411.14944v1
- Date: Fri, 22 Nov 2024 13:57:32 GMT
- Title: High-dynamic-range atomic clocks with dual Heisenberg-limited precision scaling
- Authors: Jungeng Zhou, Jiahao Huang, Jinye Wei, Chengyin Han, Chaohong Lee,
- Abstract summary: Greenberger-Horne-Zeilinger (GHZ) state is a maximally multiparticle entangled state capable of reaching the fundamental precision limit in quantum sensing.
GHZ-state-based atomic clocks hold the potential to achieve Heisenberg-limited precision but suffer from a reduced dynamic range.
Here we demonstrate how Bayesian quantum estimation can be utilized to extend the dynamic range of GHZ-state-based atomic clocks.
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- Abstract: Greenberger-Horne-Zeilinger (GHZ) state is a maximally multiparticle entangled state capable of reaching the fundamental precision limit in quantum sensing. While GHZ-state-based atomic clocks hold the potential to achieve Heisenberg-limited precision [Nature 634, 315 (2024); Nature 634, 321 (2024)], they suffer from a reduced dynamic range. Here we demonstrate how Bayesian quantum estimation can be utilized to extend the dynamic range of GHZ-state-based atomic clocks while maintaining precision close to the Heisenberg limit. In the framework of Bayesian quantum estimation, we design a sequence of correlated Ramsey interferometry for atomic clocks utilizing individual and cascaded GHZ states.In this sequence, the interrogation time is updated based on the credible intervals of the posterior distribution.By combining an interferometry sequence with short and long interrogation times, our scheme overcomes the trade-off between sensitivity and dynamic range in GHZ-state-based atomic clocks and offers an alternative approach for extending dynamic range while maintaining high sensitivity. Notably our approach enables dual Heisenberg-limited precision scaling with respect to both particle number and total interrogation time. In addition to atomic clocks, our study offers a promising avenue for developing high-dynamic-range entanglement-enhanced interferometry-based quantum sensors.
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