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The Dark Ages Explorer (DEX): a filled-aperture ultra-long wavelength radio interferometer on the lunar far side

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arxiv 2504.03418 v1 pith:RNKDMKDW submitted 2025-04-04 astro-ph.IM

The Dark Ages Explorer (DEX): a filled-aperture ultra-long wavelength radio interferometer on the lunar far side

classification astro-ph.IM
keywords agesdarkexperimentradioscientificcosmicdawndevelopment
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The measurement of the spatial fluctuations of the neutral hydrogen 21 cm signal arising during the Dark Ages and Cosmic Dawn periods of our Universe (z from 200 to 10) holds the potential to resolve these still-unexplored earliest phases of the evolution of matter structures. As these cosmological signals are very weak, large distributed telescopes are required at locations free from terrestrial radio interference and ionospheric disturbances. This paper presents a description of the scientific aims, the instrumental concept, and technological developments of an experiment - dubbed the Dark-ages EXplorer (DEX) - which would allow us to (a) measure the Global Signal and (b) measure the angular density fluctuations and conduct line-of-sight tomography in the Dark Ages and Cosmic Dawn epochs. Additional scientific goals are also briefly described. The experiment consists of a low-frequency radio interferometer, which should ideally be located on the far side of the Moon. The paper presents findings from an ESA Concurrent Design Facility (CDF) study, which was conducted to assess the feasibility of such a system using present-day technologies with a high TRL (Technology Readiness Level). Although the study finds that the number of antennas needed to achieve the primary scientific goals is not yet feasible at the moment, it points to a path of technological development that can lead to a realistic and valuable experiment in the medium-term future (i.e., the next decade(s)), as well as development of multi-purpose use technology that can be applied on Earth, and towards other lunar operations.

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Cited by 2 Pith papers

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  1. Low-frequency radio telescopes sensitivity to light dark matter

    hep-ph 2025-11 unverdicted novelty 5.0

    The study calculates sensitivity of space- and Moon-based radio telescopes to resonant light dark matter conversion in solar system targets, finding encouraging prospects for dark photon searches with the Sun and axio...

  2. Space and Lunar Interferometry: Emerging Concepts and Pathways

    astro-ph.IM 2026-07 accept novelty 3.5

    Science targets set wavelength and resolution, which fix baseline and architecture for free-flying and lunar interferometers, with shared technologies and a decade of pathfinder decisions determining which become missions.