XQC and CSR constraints on strongly interacting dark matter with spin and velocity dependent  cross sections

Li, Yonglin; Liu, Zuowei; Xue, Yingli

doi:10.1088/1475-7516/2023/05/060

Cited by 5 publications

(1 citation statement)

References 83 publications

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“…Additionally, different DM models with doubly charged particles, based on various standard model extensions [34][35][36][37][38], were discussed and elaborated to solve the contradiction of the results of an underground experiment DAMA with the results of other similar experiments. We do not fix any specific physical model here, but it is believed that such DM candidate containing a doubly charged particle, hidden inside compact neutral dark atoms, 1 may avoid different constraints of underground, (above)ground, and space experiments (see, e.g., [39]), including those based on the observation of white dwarfs [40]. As to the positron anomaly, a model with the decay X ++ → e + e + has a simple advantage as compared with the more traditional one X 0 → e + e − , since there are twice as many positrons per one FSR photon.…”

Section: Approaches To the Positron Anomaly Solution With Dark Mattermentioning

confidence: 99%

Proposition of FSR Photon Suppression Employing a Two-Positron Decay Dark Matter Model to Explain Positron Anomaly in Cosmic Rays

Barak,

Belotsky,

Shlepkina

2023

Universe

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The origin of an anomalous excess of high-energy (about 100 GeV and higher) positrons in cosmic rays is one of the rare problems in this field, which is proposed to be solved with dark matter (DM). Attempts to solve this problem are faced with the issue of having to satisfy the data on cosmic positrons and cosmic gamma radiation, which inevitably accompanies positron production, such as FSR (final state radiation), simultaneously. We have been trying to come up with a solution by means of two approaches: making assumptions (*) about the spatial distribution of the dark matter and (**) about the physics of its interactions. This work is some small final step of a big investigation regarding the search for gamma suppression by employing the second approach, and a model with a doubly charged particle decaying into two positrons (X++→e+e+) is suggested as the most prospective one from those considered before.

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Section: Approaches To the Positron Anomaly Solution With Dark Mattermentioning

confidence: 99%

Proposition of FSR Photon Suppression Employing a Two-Positron Decay Dark Matter Model to Explain Positron Anomaly in Cosmic Rays

Barak,

Belotsky,

Shlepkina

2023

Universe

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Transmon Qubit constraints on dark matter-nucleon scattering

Das,

Kurinsky,

Leane

2024

J. High Energ. Phys.

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We recently pointed out that power measurements of single quasiparticle devices can be used to detect dark matter. These devices have the lowest known energy thresholds, far surpassing standard direct detection experiments, requiring energy deposition above only about an meV. We calculate dark matter induced quasiparticle densities in transmon qubits, and use the latest transmon qubit measurements that provide one of the strongest existing lab-based bounds on dark matter-nucleon scattering below about 100 MeV. We strongly constrain sub-component dark matter, using both a dark matter population thermalized in the Earth as well as the dark matter wind from the Galactic halo. We demonstrate future potential sensitivities using devices with low quasiparticle densities.

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Search for strongly interacting dark matter at Belle II

Liang,

Liu,

Yang

2024

Phys. Rev. D

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A small component of dark matter (DM) that is strongly interacting with the standard model sector is consistent with various experimental observations. Despite the small abundance, strongly interacting DM can lead to pronounced signals in DM direct detection experiments. We study Belle II sensitivity on strongly interacting DM that has a MeV-GeV mass and couples with electrons. By taking into account the substantial interactions between DM and electrons within detectors, we compute the “ceiling” of the monophoton signature at Belle II, beyond which the monophoton channel loses its sensitivity, and visible electromagnetic calorimeter (ECL) clusters due to DM scatterings assume significance. We study two ECL signatures for strongly interacting DM: the monocluster and the dicluster channels. To carry out detailed calculations and to compare with other constraints, we consider DM models with light mediators, as they naturally lead to sizable interaction cross sections. We compute exclusion regions for the dicluster, monocluster, and monophoton channels. We find that Belle II (with currently accumulated data of 362 fb−1) can rule out a significant portion of the parameter space above the ceilings of the constraints from various DM direct detection and neutrino experiments, for the vector mediator case with mass ≳10 MeV. Belle II also offers superior constraints on new light particles compared to primordial black hole (PBH) for the scalar mediator with mass ≳10 MeV. Published by the American Physical Society 2024

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XQC and CSR constraints on strongly interacting dark matter with spin and velocity dependent cross sections

Cited by 5 publications

References 83 publications

Proposition of FSR Photon Suppression Employing a Two-Positron Decay Dark Matter Model to Explain Positron Anomaly in Cosmic Rays

Proposition of FSR Photon Suppression Employing a Two-Positron Decay Dark Matter Model to Explain Positron Anomaly in Cosmic Rays

Transmon Qubit constraints on dark matter-nucleon scattering

Search for strongly interacting dark matter at Belle II

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