Perturbations of ultralight vector field dark matter

Cembranos, J. A. R.; Maroto, Antonio L.; Jareño, S. J. Núñez

doi:10.1007/jhep02(2017)064

Cited by 34 publications

(50 citation statements)

References 84 publications

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“…For the calculations, we use the adiabatic expansion in terms of the graviton mass inverse m −1 (see Section 2.5 in [44] for calculations in the case of the scalar condensate and [45] for the vector case). We set the orders of both g µν (t) and δg µν (t, x) as O(m 0 ).…”

Section: Cosmic Structure Formationmentioning

confidence: 99%

Condensate of massive graviton and dark matter

Aoki

Maeda

2018

Phys. Rev. D

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We study coherently oscillating massive gravitons in the ghost-free bigravity theory. This coherent field can be interpreted as a condensate of the massive gravitons. We first define the effective energy-momentum tensor of the coherent massive gravitons in a curved spacetime. We then study the background dynamics of the universe and the cosmic structure formation including the effects of the coherent massive gravitons. We find that the condensate of the massive graviton behaves as a dark matter component of the universe. From the geometrical point of view the condensate is regarded as a spacetime anisotropy. Hence, in our scenario, dark matter is originated from the tiny deformation of the spacetime. We also discuss a production of the spacetime anisotropy and find that the extragalactic magnetic field of a primordial origin can yield a sufficient amount for dark matter.

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Section: Cosmic Structure Formationmentioning

confidence: 99%

Condensate of massive graviton and dark matter

Aoki

Maeda

2018

Phys. Rev. D

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“…Although the work on ultralight fields has been mainly concerned with scalar fields, there are recent results on higher spin fields. It has been shown that abelian vectors at the background [22] and perturbation level [23], non-abelian vectors [24] and arbitrary-spin fields [25] behave in a similar way. Interestingly, the results of [25] show that it is possible to achieve an isotropic model of higher-spin dark matter as long as it is rapidly oscillating.…”

Section: Jhep08(2018)073mentioning

confidence: 99%

Constraints on anharmonic corrections of fuzzy dark matter

Cembranos

Maroto

Jareño

et al. 2018

J. High Energ. Phys.

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The cold dark matter (CDM) scenario has proved successful in cosmology. However, we lack a fundamental understanding of its microscopic nature. Moreover, the apparent disagreement between CDM predictions and subgalactic-structure observations has prompted the debate about its behaviour at small scales. These problems could be alleviated if the dark matter is composed of ultralight fields m ∼ 10 −22 eV, usually known as fuzzy dark matter (FDM). Some specific models, with axion-like potentials, have been thoroughly studied and are collectively referred to as ultralight axions (ULAs) or axion-like particles (ALPs). In this work we consider anharmonic corrections to the mass term coming from a repulsive quartic self-interaction. Whenever this anharmonic term dominates, the field behaves as radiation instead of cold matter, modifying the time of matter-radiation equality. Additionally, even for high masses, i.e. masses that reproduce the cold matter behaviour, the presence of anharmonic terms introduce a cut-off in the matter power spectrum through its contribution to the sound speed. We analyze the model and derive constraints using a modified version of class and comparing with CMB and large-scale structure data.

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“…In fact, although the coherent state of the DP may have a particular polarization, it has associated an isotropic average energy-momentum tensor [9,12] and supports isotropic cosmologies. In any case, bounds on the DP mass can be obtained from supporting a proper structure formation in the early Universe [13,14].…”

Section: Dark Photonsmentioning

confidence: 99%

Dark photon searches with atomic transitions

Álvarez-Luna

Cembranos

2019

J. High Energ. Phys.

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Dark matter could be made up of dark photons, massive but very light particles whose interactions with matter resemble those of usual photons but suppressed by a small mixing parameter. We analyze the main approaches to dark photon interactions and how they can be applied to direct detection experiments which test different ranges of masses and mixings. A new experiment based on counting dark photons from induced atomic transitions in a target material is proposed. This approach appears to be particularly appropriate for dark photon detection in the meV mass range, extending the constraints in the mixing parameter by up to eight orders of magnitude with respect to previous experiments.

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Perturbations of ultralight vector field dark matter

Cited by 34 publications

References 84 publications

Condensate of massive graviton and dark matter

Condensate of massive graviton and dark matter

Constraints on anharmonic corrections of fuzzy dark matter

Dark photon searches with atomic transitions

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