A space-based quantum gas laboratory at picokelvin energy scales

Gaaloul, Naceur; Meister, Matthias; Corgier, Robin; Annie, Pichery,; Boegel, Patrick; Herr, Waldemar; Ahlers, Holger; Charron, Eric; Williams, Jason; Thompson, Robert J.; Schleich, Wolfgang P.; Rasel, Ernst M.; Bigelow, N. P.

doi:10.1038/s41467-022-35274-6

Cited by 36 publications

(19 citation statements)

References 63 publications

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“…On the overall, the input four-mode entangled state proposed in Fig. 1a could be experimentally generated with a suitable combination of Raman and Bragg diffraction, on ground fountain experiment [26,81] or in space environment [82] for example. Based on recent experimental development and new methods in the field, we highlight a possible experimental sequence with Bose-Einstein condensate (BEC).…”

Section: Possible Experimental Implementation With Bose-einstein Cond...mentioning

confidence: 99%

Quantum-enhanced differential atom interferometers and clocks with spin-squeezing swapping

Corgier

Malitesta

Smerzi

et al. 2023

Quantum

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Thanks to common-mode noise rejection, differential configurations are crucial for realistic applications of phase and frequency estimation with atom interferometers. Currently, differential protocols with uncorrelated particles and mode-separable settings reach a sensitivity bounded by the standard quantum limit (SQL). Here we show that differential interferometry can be understood as a distributed multiparameter estimation problem and can benefit from both mode and particle entanglement. Our protocol uses a single spin-squeezed state that is mode-swapped among common interferometric modes. The mode swapping is optimized to estimate the differential phase shift with sub-SQL sensitivity. Numerical calculations are supported by analytical approximations that guide the optimization of the protocol. The scheme is also tested with simulation of noise in atomic clocks and interferometers.

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Section: Possible Experimental Implementation With Bose-einstein Cond...mentioning

confidence: 99%

Quantum-enhanced differential atom interferometers and clocks with spin-squeezing swapping

Corgier

Malitesta

Smerzi

et al. 2023

Quantum

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“…Operation in a microgravity environment could boost the sensivity of such sensors by increasing the free-fall time of the atoms during the interferometry sequence, a critical parameter for the scaling factor (Kasevich & Chu, 1991), leading to anticipated noise levels of 0.1 nm s −2 Hz −1/2 and below (Dickerson et al, 2013). Multiple experiments implemented and investigated atom optics and atom interferometry in microgravity, including the production of Bose-Einstein condensates followed by a matter-wave collimation step, enabling the ultra-low expansion rates of the atomic ensembles for compatibility with extended free-fall times (Gaaloul et al, 2022;Lachmann et al, 2021;Aveline et al, 2020;Becker et al, 2018;Rudolph et al, 2015;Müntinga et al, 2013;Geiger et al, 2011;van Zoest et al, 2010). Operating atom interferometers at high data rates currently either implies an increased noise level due to short free-fall times (Rakholia et al, 2014) or an increased complexity when implementing an interleaved mode (Savoie et al, 2018).…”

Section: Primary Instrumentmentioning

confidence: 99%

MaQuIs - Mars Quantum Gravity Mission

Wörner

Root

Bouyer³

et al. 2023

Preprint

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The aim of this paper is to propose a Mars Quantum Gravity Mission (MaQuIs). The mission is targeted at improving the data on the gravitational field of Mars, enabling studies on planetary dynamics, seasonal changes, and subsurface water reservoirs. MaQuIs follows well known mission scenarios, currently deployed for Earth, and includes state-of-the-art quantum technologies to enhance the gained scientific signal.

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“…There are methods to engineer the expansion rates of the mixture by switching on for a short time, and after the clouds have expanded, a trapping potential that acts as a matter-wave lens. This delta-kick collimation technique [27,28,[34][35][36][37][38][39][40] reduces the kinetic energy of the system and enables very low expansion rates, which are mandatory for high-precision interferometry in microgravity. However, in order to control the expansion rates of a mixture in all spatial dimensions, one lens per independent direction is required for each species, rendering a full 3D implementation rather impractical and error prone.…”

Section: Introductionmentioning

confidence: 99%

Efficient matter-wave lensing of ultracold atomic mixtures

Meister¹,

Roura²

2023

Quantum Sci. Technol.

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Mixtures of ultracold quantum gases are at the heart of high-precision quantum tests of the weak equivalence principle, where extremely low expansion rates have to be reached with matter-wave lensing techniques. We propose to simplify this challenging atom-source preparation by employing magic laser wavelengths for the optical lensing potentials, which guarantee that all atomic species follow identical trajectories and experience common expansion dynamics. In this way, the relative shape of the mixture is conserved during the entire evolution while cutting in half the number of required lensing pulses compared to standard approaches.

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A space-based quantum gas laboratory at picokelvin energy scales

Cited by 36 publications

References 63 publications

Quantum-enhanced differential atom interferometers and clocks with spin-squeezing swapping

Quantum-enhanced differential atom interferometers and clocks with spin-squeezing swapping

MaQuIs - Mars Quantum Gravity Mission

Efficient matter-wave lensing of ultracold atomic mixtures

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