S. Hedges scite author profile

We outline the experimental concept and key scientific capabilities of AION (Atom Interferometer Observatory and Network), a proposed experimental programme using cold strontium atoms to search for ultra-light dark matter, to explore gravitational waves in the mid-frequency range between the peak sensitivities of the LISA and LIGO/Virgo/ KAGRA/INDIGO/Einstein Telescope/Cosmic Explorer experiments, and to probe other frontiers in fundamental physics. AION would complement other planned searches for dark matter, as well as probe mergers involving intermediate-mass black holes and explore early-universe cosmology. AION would share many technical features with the MAGIS experimental programme, and synergies would flow from operating AION in a network with this experiment, as well as with other atom interferometer experiments such as MIGA, ZAIGA and ELGAR. Operating AION in a network with other gravitational wave detectors such as LIGO, Virgo and LISA would also offer many synergies.

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Rigorous Analysis and Network Modeling of the Inset Dielectric Guide

Rozzi

Hedges²

1987

IEEE Trans. Microwave Theory Techn.

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Circulating pulse cavity enhancement as a method for extreme momentum transfer atom interferometry

et al. 2021

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Large-scale atom interferometers promise unrivaled strain sensitivity to mid-band gravitational waves, and will probe a new parameter space in the search for ultra-light scalar dark matter. These proposals require gradiometry with kilometer-scale baselines, a momentum separation above 104ℏk between interferometer arms, and optical transitions to long-lived clock states to reach the target sensitivities. Prohibitively high optical power and wavefront flatness requirements have thus far limited the maximum achievable momentum splitting. Here we propose a scheme for optical cavity enhanced atom interferometry, using circulating, spatially resolved pulses, and intracavity frequency modulation to meet these requirements. We present parameters for the realization of 20 kW circulating pulses in a 1 km interferometer enabling 104ℏk splitting on the 698 nm clock transition in 87Sr. This scheme addresses the presently insurmountable laser power requirements and is feasible in the context of a kilometer-scale atom interferometer facility.

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The Analysis of Inset Dielectric Guide using Transverse Resonance Diffraction

Hedges¹,

Rozzi

1985

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Circulating pulse cavity enhancement as a method for extreme momentum transfer atom interferometry

Nourshargh

Lellouch

Hedges

et al. 2020

Preprint

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S. Hedges

AION: an atom interferometer observatory and network

Rigorous Analysis and Network Modeling of the Inset Dielectric Guide

Circulating pulse cavity enhancement as a method for extreme momentum transfer atom interferometry

The Analysis of Inset Dielectric Guide using Transverse Resonance Diffraction

Circulating pulse cavity enhancement as a method for extreme momentum transfer atom interferometry

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