Jordan Dudley scite author profile

Atom interferometry has become one of the most powerful technologies for precision measurements. In order to develop simple, precise and versatile atom interferometers for inertial sensing, we demonstrate an atom interferometer measuring acceleration, rotation, and inclination by pointing Raman beams toward individual faces of a pyramidal mirror. Only a single diode laser is used for all functions, including atom trapping, interferometry, and detection. Efficient Doppler-sensitive Raman transitions are achieved without velocity selecting the atom sample, and with zero differential AC Stark shift between the cesium hyperfine ground states, increasing signal-to-noise and suppressing systematic effects. We measure gravity along two axes (vertical and 45 • to the vertical), rotation, and inclination with sensitivities of 6 µm/s 2 / √ Hz, 300 µrad/s/ √ Hz, and 4 µrad/ √ Hz, respectively. This work paves the way toward deployable multiaxis atom interferometers for geodesy, geology, or inertial navigation.

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A dual‐isotope rubidium comagnetometer to search for anomalous long‐range spin‐mass (spin‐gravity) couplings of the proton

Kimball

Lacey

Valdez

et al. 2013

Annalen der Physik

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The experimental concept of a search for a long-range coupling between rubidium (Rb) nuclear spins and the mass of the Earth is described. The experiment is based on simultaneous measurement of the spin precession frequencies for overlapping ensembles of 85 Rb and 87 Rb atoms contained within an evacuated, antirelaxation-coated vapor cell. Rubidium atoms are spin-polarized in the presence of an applied magnetic field by synchronous optical pumping with circularly polarized laser light. Spin precession is probed by measuring optical rotation of far-off-resonant, linearly polarized laser light. Simultaneous measurement of 85 Rb and 87 Rb spin precession frequencies enables suppression of magnetic-field-related systematic effects. The nuclear structure of the Rb isotopes makes the experiment particularly sensitive to anomalous spin-dependent interactions of the proton. Experimental sensitivity and a variety of systematic effects are discussed, and initial data are presented.

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Constraints on long-range spin-gravity and monopole-dipole couplings of the proton

Kimball

Dudley

et al. 2017

Phys. Rev. D

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Results of a search for a long-range monopole-dipole coupling between the mass of the Earth and rubidium (Rb) nuclear spins are reported. The experiment simultaneously measures the spin precession frequencies of overlapping ensembles of 85 Rb and 87 Rb atoms contained within an evacuated, antirelaxation-coated vapor cell. The nuclear structure of the Rb isotopes makes the experiment particularly sensitive to spin-dependent interactions of the proton. The spin-dependent component of the gravitational energy of the proton in the Earth's field is found to be smaller than 3×10 −18 eV, improving laboratory constraints on long-range monopole-dipole interactions by over three orders of magnitude.

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Magnetic shielding and exotic spin-dependent interactions

Kimball

Dudley

et al. 2016

Phys. Rev. D

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Experiments searching for exotic spin-dependent interactions typically employ magnetic shielding between the source of the exotic field and the interrogated spins. We explore the question of what effect magnetic shielding has on detectable signals induced by exotic fields. Our general conclusion is that for common experimental geometries and conditions, magnetic shields should not significantly reduce sensitivity to exotic spin-dependent interactions, especially when the technique of comagnetometry is used. However, exotic fields that couple to electron spin can induce magnetic fields in the interior of shields made of a soft ferro-or ferrimagnetic material. This induced magnetic field must be taken into account in the interpretation of experiments searching for new spin-dependent interactions and raises the possibility of using a flux concentrator inside magnetic shields to amplify exotic spin-dependent signals.

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Erratum: Constraints on long-range spin-gravity and monopole-dipole couplings of the proton [Phys. Rev. D 96 , 075004 (2017)]

Kimball¹,

Dudley²,

Li³

et al. 2023

Phys. Rev. D

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Jordan Dudley

Multiaxis atom interferometry with a single-diode laser and a pyramidal magneto-optical trap

A dual‐isotope rubidium comagnetometer to search for anomalous long‐range spin‐mass (spin‐gravity) couplings of the proton

Constraints on long-range spin-gravity and monopole-dipole couplings of the proton

Magnetic shielding and exotic spin-dependent interactions

Erratum: Constraints on long-range spin-gravity and monopole-dipole couplings of the proton [Phys. Rev. D 96 , 075004 (2017)]

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