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Low Frequency Gravitational Wave Detection With Ground Based Atom Interferometer Arrays

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arxiv 1601.00417 v1 pith:YJG343LZ submitted 2016-01-04 physics.atom-ph gr-qcphysics.ins-det

Low Frequency Gravitational Wave Detection With Ground Based Atom Interferometer Arrays

classification physics.atom-ph gr-qcphysics.ins-det
keywords atomtextarraybelowcurrentdetectorsbaselineconfiguration
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We propose a new detection strategy for gravitational waves (GWs) below few Hertz based on a correlated array of atom interferometers (AIs). Our proposal allows to reduce the Newtonian Noise (NN) which limits all ground based GW detectors below few Hertz, including previous atom interferometry-based concepts. Using an array of long baseline AI gradiometers yields several estimations of the NN, whose effect can thus be reduced via statistical averaging. Considering the km baseline of current optical detectors, a NN rejection of factor 2 could be achieved, and tested with existing AI array geometries. Exploiting the correlation properties of the gravity acceleration noise, we show that a 10-fold or more NN rejection is possible with a dedicated configuration. Considering a conservative NN model and the current developments in cold atom technology, we show that strain sensitivities below $1\times 10^{-19}/ \sqrt{\text{Hz}}$ in the $ 0.3-3 \ \text{Hz}$ frequency band can be within reach, with a peak sensitivity of $3\times 10^{-23}/ \sqrt{\text{Hz}} $ at $2 \ \text{Hz}$. Our proposed configuration could extend the observation window of current detectors by a decade and fill the gap between ground-based and space-based instruments.

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