Limitations for field-enhanced atom interferometry

Comparat, D.

doi:10.1103/physreva.101.023606

Cited by 6 publications

(5 citation statements)

References 84 publications

(105 reference statements)

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“…In addition, our atom chip setup is compatible with cryogenic environments and may hence probe cold surfaces, while laser light may cause unwanted heating. Last, know-how described in this work may assist to advance also other interferometric configurations that use static fields, e.g., electric fields ( 26 , 27 ).…”

Section: Introductionmentioning

confidence: 92%

Realization of a complete Stern-Gerlach interferometer: Toward a test of quantum gravity

et al. 2021

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The Stern-Gerlach effect, found a century ago, has become a paradigm of quantum mechanics. Unexpectedly, until recently, there has been little evidence that the original scheme with freely propagating atoms exposed to gradients from macroscopic magnets is a fully coherent quantum process. Several theoretical studies have explained why a Stern-Gerlach interferometer is a formidable challenge. Here, we provide a detailed account of the realization of a full-loop Stern-Gerlach interferometer for single atoms and use the acquired understanding to show how this setup may be used to realize an interferometer for macroscopic objects doped with a single spin. Such a realization would open the door to a new era of fundamental probes, including the realization of previously inaccessible tests at the interface of quantum mechanics and gravity.

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Section: Introductionmentioning

confidence: 92%

Realization of a complete Stern-Gerlach interferometer: Toward a test of quantum gravity

et al. 2021

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“…We highlight that the magnetic-field gradient pulse can provide an additional control in the momentum transfer δp to increase the sensitivity of the interferometer compared with using the conventional laser pulses [53]. One in Eq.…”

Section: B Magnetic-field Gradient Pulse Regimementioning

confidence: 99%

“…As recently pointed out in Ref. [53], the laser-pulse-based atomic interferometer has a limitation of increasing the momentum difference of the wave packets while employing external fields to give a momentum difference may resolve this drawback. As a remark, since the difference between the initial and final positions is required to be large, it is beneficial to have the direction of an initial velocity to be the same as that of the linear force.…”

Section: Conventional Butterfly Interferometermentioning

confidence: 99%

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Field-gradient measurement using a Stern-Gerlach atomic interferometer with butterfly geometry

Kwon

Jiang

et al. 2020

Phys. Rev. A

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Atomic interferometers have been studied as a promising device for precise sensing of external fields. Among various configurations, a particular configuration with a butterfly-shaped geometry has been designed to sensitively probe field gradients. We introduce a Stern-Gerlach (SG) butterfly interferometer by incorporating magnetic field in the conventional butterfly-shaped configuration. Atomic trajectories of the interferometer can be flexibly adjusted by controlling magnetic fields to increase the sensitivity of the interferometer, while the conventional butterfly interferometer using Raman transitions can be understood as a special case. We also show that the SG interferometer can keep high contrast against a misalignment in position and momentum caused by the field gradient.

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“…In reality, a high-quality interference based on the quality of a quantum system is still very limited due to the imperfect stability of external magnetic or optical fields under real implementation, which can sensitively dephase the interference by artificial measurement or noise effect. [17] Although a large number of approaches for overcoming the instability or imperfect measurement have been proposed, e.g., quantum nondemolition measurement allows repeated detection of quantum states without destroying them; [18] quantum plasmonics experiments exhibit remarkable preservation of coherence, [19] a more precise atom interferometry is achieved by transferring the photon momentum to atoms while minimizing its uncertainty; [20] however it is still challenging for realizing extremely stable quantum interference in a well-defined isolated system.…”

Section: Introductionmentioning

confidence: 99%

Stable quantum interference enabled by coexisting detuned and resonant STIRAPs*

Liu¹,

Gao²,

Xu³

et al. 2021

Chinese Phys. B

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Inspired by a recent experiment [Phys. Rev. Lett. 122 253201(2019)] that an unprecedented quantum interference was observed in the way of stimulated Raman adiabatic passage (STIRAP) due to the coexisting resonant- and detuned-STIRAPs, we comprehensively study this effect. Our results uncover the scheme robustness towards any external-field fluctuations coming from laser intensity noise and imperfect resonance condition, as well as the persistence of high-contrast interference pattern even when more nearby excited levels are involved. We verify that an auxiliary dynamical phase accumulated in hold time caused by the presence of the quasi-dark state in detuned-STIRAP can sensitively manipulate the visibility and frequency of the interference pattern, representing a new hallmark to measure the hyperfine energy accurately. The robust stability of the scheme comes from the intrinsic superiority embedded in the STIRAP mechanism that preserves the coherence of population transfer, which promises a remarkable performance of quantum interference in a practical implementation.

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Limitations for field-enhanced atom interferometry

Cited by 6 publications

References 84 publications

Realization of a complete Stern-Gerlach interferometer: Toward a test of quantum gravity

Realization of a complete Stern-Gerlach interferometer: Toward a test of quantum gravity

Field-gradient measurement using a Stern-Gerlach atomic interferometer with butterfly geometry

Stable quantum interference enabled by coexisting detuned and resonant STIRAPs*

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