Dark matter local density determination based on recent observations

Salas, Pablo F. de

doi:10.1088/1742-6596/1468/1/012020

Cited by 17 publications

(12 citation statements)

References 136 publications

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“…Here, ρ ¼ 0.45 GeV=cm 3 is the local DM density (the value assumed in, e.g., Ref. [70] and compatible with observations [71][72][73]), V d is the fiducial volume of the detector, and κ is the signal coupling efficiency factor. In Appendix, we employ the machinery of thermal field theory to directly compute the power absorbed by the detector in the "propagator approach" [55].…”

Section: Output Powermentioning

confidence: 97%

Probing dark photons with plasma haloscopes

et al. 2020

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Dark photons (DPs) produced in the early Universe are well-motivated dark matter (DM) candidates. We show that the recently proposed tunable plasma haloscopes are particularly advantageous for DP searches. While in-medium effects suppress the DP signal in conventional searches, plasma haloscopes make use of metamaterials that enable resonant absorption of the DP by matching its mass to a tunable plasma frequency and thus enable efficient plasmon production. Using thermal field theory, we confirm the in-medium DP absorption rate within the detector. This scheme allows us to competitively explore a significant part of the DP DM parameter space in the DP mass range of 6-400 μeV. If a signal is observed, the observation of a daily or annual modulation of the signal would be crucial to clearly identify the signal as due to DP DM and could shed light on the production mechanism.

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Section: Output Powermentioning

confidence: 97%

Probing dark photons with plasma haloscopes

et al. 2020

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“…Ref. [63] and compatible with observations [64][65][66]), V d is the fiducial volume of the detector, and κ is the signal coupling efficiency factor.…”

Section: Output Powermentioning

confidence: 70%

Probing dark photons with plasma haloscopes

Gelmini,

Millar,

Takhistov

et al. 2020

Preprint

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“…Evidence for the existence of dark matter was discovered via its gravitational effects on large scale dynamics, and new astronomical probes promise to establish additional constraints on its physical nature [14]. Astronomical observations [15,16] jointly give the energy density of dark matter, ρ DM , at our position in our Galaxy: 380±180 TeV/m 3 . For dark photons in free space, converting this energy density to its corresponding observed electric field gives [13]…”

Section: Femtovolt Time-spectrum Detectormentioning

confidence: 97%

Search for Dark Photon Dark Matter: Dark E-Field Radio Pilot Experiment

Godfrey,

Tyson,

Hillbrand

et al. 2021

Preprint

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We are building an experiment to search for dark matter in the form of dark photons in the nano-to milli-eV mass range. This experiment is the electromagnetic dual of magnetic detector dark radio experiments. It is also a frequency-time dual experiment in two ways: We search for a high-Q signal in wide-band data rather than tuning a high-Q resonator, and we measure electric rather than magnetic fields. In this paper we describe a pilot experiment using room temperature electronics which demonstrates feasibility and sets useful limits to the kinetic coupling ∼ 10 −12 over 50-300 MHz. With a factor of 2000 increase in real-time spectral coverage, and lower system noise temperature, it will soon be possible to search a wide range of masses at 100 times this sensitivity. We describe the planned experiment in two phases: Phase-I will implement a wide band, 5-million channel, real-time FFT processor over the 30-300 MHz range with a back-end time-domain optimal filter to search for the predicted Q ∼ 10 6 line using low-noise amplifiers. We have completed spot frequency calibrations using a biconical dipole antenna in a shielded room that extrapolate to a 5 σ limit of ∼ 10 −13 for the coupling from the dark field, per month of integration. Phase-II will extend the search to 20 GHz using cryogenic preamplifiers and new antennas.

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Dark matter local density determination based on recent observations

Cited by 17 publications

References 136 publications

Probing dark photons with plasma haloscopes

Probing dark photons with plasma haloscopes

Probing dark photons with plasma haloscopes

Search for Dark Photon Dark Matter: Dark E-Field Radio Pilot Experiment

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