Single phonon detection for dark matter via quantum evaporation and sensing of 
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Lyon, S. A.; Castoria, Kyle; Kleinbaum, Ethan; Qin, Zhihao; Persaud, Arun; Schenkel, Thomas; Zurek, Kathryn M.

doi:10.1103/physrevd.109.023010

Phys. Rev. D

2024

DOI: 10.1103/physrevd.109.023010

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Single phonon detection for dark matter via quantum evaporation and sensing of He3

S. A. Lyon,

Kyle Castoria,

Ethan Kleinbaum

et al.

Abstract: Dark matter is five times more abundant than ordinary visible matter in our Universe. While laboratory searches hunting for dark matter have traditionally focused on the electroweak scale, theories of low mass hidden sectors motivate new detection techniques. Extending these searches to lower mass ranges, well below 1 GeV/c2, poses new challenges as rare interactions with standard model matter transfer progressively less energy to electrons and nuclei in detectors. Here, we propose an approach based on phonon… Show more

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Cited by 3 publications

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Superfluid helium ultralight dark matter detector

Hirschel,

Vadakkumbatt,

Baker

et al. 2024

Phys. Rev. D

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Superfluid helium ultralight dark matter detector

Hirschel,

Vadakkumbatt,

Baker

et al. 2024

Phys. Rev. D

View full text Add to dashboard Cite

Optomechanical dark matter instrument for direct detection

Baker,

Bowen,

Cox

et al. 2024

Phys. Rev. D

View full text Add to dashboard Cite

We propose the Optomechanical Dark-matter Instrument (ODIN), based on a new method for the direct detection of low-mass dark matter. We consider dark matter interacting with superfluid helium in an optomechanical cavity. Using an effective field theory, we calculate the rate at which dark matter scatters off phonons in a highly populated, driven acoustic mode of the cavity. This scattering process deposits a phonon into a second acoustic mode in its ground state. The deposited phonon (μeV range) is then converted to a photon (eV range) via an optomechanical interaction with a pump laser. This photon can be efficiently detected, providing a means to sensitively probe keV scale dark matter. We provide realistic estimates of the backgrounds and discuss the technical challenges associated with such an experiment. We calculate projected limits on dark matter–nucleon interactions for dark matter masses ranging from 0.5 to 300 keV and estimate that a future device could probe cross sections as low as O(10−32) cm2. Published by the American Physical Society 2024

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Factors influencing quantum evaporation of helium from polar semiconductors from first principles

Dheer,

Tan,

Lyon

et al. 2024

Phys. Rev. D

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While there is much indirect evidence for the existence of dark matter (DM), to date it has evaded detection. Current efforts focus on DM masses over ∼GeV—to push the sensitivity of DM searches to lower masses, new DM targets and detection schemes are needed. In this work, we focus on the latter—a novel detection scheme recently proposed to detect 10–100 meV phonons in polar target materials. Previous work showed that well-motivated models of DM can interact with polar semiconductors to produce an athermal population of phonons. This new sensing scheme proposes that these phonons then facilitate quantum evaporation of He3 from a van der Waals film deposited on the target material. However, a fundamental understanding of the underlying process is still unclear, with several uncertainties related to the precise rate of evaporation and how it can be controlled. In this work, we use density functional theory calculations to compare the adsorption energies of helium atoms on a polar target material, sodium iodide, to understand the underlying evaporation physics. We explore the role of surface termination, monolayer coverage, and elemental species on the rate of He evaporation from the target material. Using this, we discuss the optimal target features for He-evaporation experiments and their range of tunability through chemical and physical modifications such as applied field and surface termination. Published by the American Physical Society 2024

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Single phonon detection for dark matter via quantum evaporation and sensing of He3

Cited by 3 publications

References 57 publications

Superfluid helium ultralight dark matter detector

Superfluid helium ultralight dark matter detector

Optomechanical dark matter instrument for direct detection

Factors influencing quantum evaporation of helium from polar semiconductors from first principles

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