An atomic gravitational wave interferometric sensor in low earth orbit (AGIS-LEO)

Hogan, Jason; Johnson, David M.; Dickerson, Susannah; Kovachy, Tim; Sugarbaker, Alex; Chiow, Sheng‐wey; Graham, Peter W.; Kasevich, Mark A.; Saif, Babak; Rajendran, Surjeet; Bouyer, Philippe; Seery, Bernard D.; Feinberg, Lee; Keski-Kuha, Ritva

doi:10.1007/s10714-011-1182-x

Cited by 173 publications

(231 citation statements)

References 93 publications

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“…As for the beam jitter case, noise from small-scale aberrations is strongly suppressed [22], and we can focus on the largest scale aberration for the noise estimate, which corresponds to a spatial wavelength equal to half of the beam diameter. In this case, assuming a mirror at room temperature with a coating quality factor Q = 10 4 , the atom phase noise at 0.1 Hz in units of GW strain is less than 10 −24 / √ Hz.…”

Section: Figmentioning

confidence: 99%

Low-frequency terrestrial gravitational-wave detectors

et al. 2013

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Direct detection of gravitational radiation in the audio band is being pursued with a network of kilometer-scale interferometers (LIGO, Virgo, KAGRA). Several space missions (LISA, DECIGO, BBO) have been proposed to search for sub-Hz radiation from massive astrophysical sources. Here we examine the potential sensitivity of three ground-based detector concepts aimed at radiation in the 0.1 -10 Hz band. We describe the plethora of potential astrophysical sources in this band and make estimates for their event rates and thereby, the sensitivity requirements for these detectors. The scientific payoff from measuring astrophysical gravitational waves in this frequency band is great. Although we find no fundamental limits to the detector sensitivity in this band, the remaining technical limits will be extremely challenging to overcome.

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Section: Figmentioning

confidence: 99%

Low-frequency terrestrial gravitational-wave detectors

et al. 2013

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“…Furthermore, a detailed study of the noise budget for a realistic detector is mandatory to have a reliable comparison between optical and atom interferometers. Florence-Urbino group, among others [35][36][37], is developing a facility as a preliminary fundamental step to test the feasibility of this new GW detector.…”

Section: Discussionmentioning

confidence: 99%

Principles of Gravitational Waves Detection Through Atom Interferometry

Vetrano

Guidi

Viceré

et al. 2013

Int. J. Mod. Phys. Conf. Ser.

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The output of a simple Mach-Zehnder atom interferometer (with light field beam splitters) is studied in order to obtain sensitivity curves for GW signals in the paraxial approximation by using the ABCD matrices techniques and first order perturbation theory for mirroratom interaction; order of magnitude of relevant physical parameters for a realistic GW detector through atom interferometry is deduced, both for single-and coupled-interferometers configurations. Finally a synthetic overview of ongoing activities of the Florence-Urbino group in this field is presented.

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“…This term, already introduced in a different context [34], is a sort of "clock" term which takes into account the influence of the GW on the laser beam, along its path from the source to a well defined physical point. Its role was discussed in recent papers [35][36][37] and the most relevant new property is the introduction of q 1 (path of laser beam) in place of L (path of atom beam); so, in order to improve the sensitivity, enlarging q 1 seems in principle easier than enlarging L.…”

Section: Two Detectors Operated In a Differential Configurationmentioning

confidence: 99%

Newtonian noise limit in atom interferometers for gravitational wave detection

Vetrano

Viceré

2013

Eur. Phys. J. C

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In this work we study the influence of the Newtonian noise on atom interferometers applied to the detection of gravitational waves, and we compute the resulting limits to the sensitivity in two different configurations: a single atom interferometer, or a pair of atom interferometers operated in a differential configuration. We find that for the instrumental configurations considered, and operating in the frequency range [0.1-10] Hz, the limits would be comparable to those affecting large scale optical interferometers.

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An atomic gravitational wave interferometric sensor in low earth orbit (AGIS-LEO)

Cited by 173 publications

References 93 publications

Low-frequency terrestrial gravitational-wave detectors

Low-frequency terrestrial gravitational-wave detectors

Principles of Gravitational Waves Detection Through Atom Interferometry

Newtonian noise limit in atom interferometers for gravitational wave detection

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