Substructure lensing in galaxy clusters as a constraint on low-mass sterile neutrinos in tensor-vector-scalar theory: The straight arc of Abell 2390

Feix, Martin; Zhao, Hongsheng; Fedeli, C.; Pestaña, José Luis G.; Hoekstra, Henk

doi:10.1103/physrevd.82.124003

Cited by 13 publications

(8 citation statements)

References 140 publications

(251 reference statements)

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“…Some of the dynamical mass must be provided, as expected, by the central galaxies, but the required amount implies a mass-to-light ratio of 1.2M ⊙ /L ⊙ in the K band, in agreement with stellar population synthesis models. An 11 eV sterile neutrino is also consistent with the straight arc, originated by a strong lensing effect, observed in the cluster A2390 [49].…”

Section: The Role Of An 11 Ev Sterile Neutrinosupporting

confidence: 80%

The Acceleration Scale, Modified Newtonian Dynamics, and Sterile Neutrinos

Diaferio¹,

Angus²

2012

Preprint

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General Relativity is able to describe the dynamics of galaxies and larger cosmic structures only if most of the matter in the Universe is dark, namely it does not emit any electromagnetic radiation. Intriguingly, on the scale of galaxies, there is strong observational evidence that the presence of dark matter appears to be necessary only when the gravitational field inferred from the distribution of the luminous matter falls below an acceleration of the order of 10 −10 m s −2 . In the standard model, which combines Newtonian gravity with dark matter, the origin of this acceleration scale is challenging and remains unsolved. On the contrary, the full set of observations can be neatly described, and were partly predicted, by a modification of Newtonian dynamics, dubbed MOND, that does not resort to the existence of dark matter. On the scale of galaxy clusters and beyond, however, MOND is not as successful as on the scale of galaxies, and the existence of some dark matter appears unavoidable. A model combining MOND with hot dark matter made of sterile neutrinos seems to be able to describe most of the astrophysical phenomenology, from the power spectrum of the cosmic microwave background anisotropies to the dynamics of dwarf galaxies. Whether there exists a yet unknown covariant theory that contains General Relativity and Newtonian gravity in the weak field limit, and MOND as the ultra-weak field limit is still an open question.

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Section: The Role Of An 11 Ev Sterile Neutrinosupporting

confidence: 80%

The Acceleration Scale, Modified Newtonian Dynamics, and Sterile Neutrinos

Diaferio¹,

Angus²

2012

Preprint

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“…Again, it was shown that the density of missing mass was compatible with 2 eV ordinary neutrinos, like in most clusters with T > 4 keV [140]. Finally, let us note that strong lensing was also recently used as a robust probe of the matter distribution on scales of 100 kpc in galaxy clusters, especially in the cluster Abell 2390 [150]. A residual missing mass was again found, compatible with the densities provided by fermionic hot dark matter candidates only for masses of ∼ 10 eV and heavier.…”

Section: Strong and Weak Lensing By Galaxy Clustersmentioning

confidence: 84%

Modified Newtonian Dynamics (MOND): Observational Phenomenology and Relativistic Extensions

Famaey

McGaugh

2012

Living Rev. Relativ.

887

1,303

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A wealth of astronomical data indicate the presence of mass discrepancies in the Universe. The motions observed in a variety of classes of extragalactic systems exceed what can be explained by the mass visible in stars and gas. Either (i) there is a vast amount of unseen mass in some novel form — dark matter — or (ii) the data indicate a breakdown of our understanding of dynamics on the relevant scales, or (iii) both. Here, we first review a few outstanding challenges for the dark matter interpretation of mass discrepancies in galaxies, purely based on observations and independently of any alternative theoretical framework. We then show that many of these puzzling observations are predicted by one single relation — Milgrom’s law — involving an acceleration constant a0 (or a characteristic surface density Σ† = a0/G) on the order of the square-root of the cosmological constant in natural units. This relation can at present most easily be interpreted as the effect of a single universal force law resulting from a modification of Newtonian dynamics (MOND) on galactic scales. We exhaustively review the current observational successes and problems of this alternative paradigm at all astrophysical scales, and summarize the various theoretical attempts (TeVeS, GEA, BIMOND, and others) made to effectively embed this modification of Newtonian dynamics within a relativistic theory of gravity.

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“…1) in small galaxies and in the solar system [14]. Additionally, there will be only very mild (< 50%) variations of A 0 inside galaxies, as well as between galaxies, small variations which might be desirable to explain some anomalies in strong lensing galaxies [15][16][17][18][19]. In any case this scatter is acceptable as the MOND formula works for all galaxies as long as a 0 is within the range between 0.9 and 1.7 × 10 −10 m s −2 [13,20].…”

Section: A Realistic Effective Variation Of the Acceleration Scalementioning

confidence: 99%

Unifying all mass discrepancies with one effective gravity law?

Zhao

Famaey

2012

Phys. Rev. D

Self Cite

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A remarkably tight relation is observed between the Newtonian gravity sourced by the baryons and the actual gravity in galaxies of all sizes. This can be interpreted as the effect of a single effective force law depending on acceleration. This is however not the case in larger systems with much deeper potential wells, such as galaxy clusters. Here we explore the possibility of an effective force law reproducing mass discrepancies in all extragalactic systems when depending on both acceleration and the depth of the potential well. We exhibit, at least at a phenomenological level, one such possible construction in the classical gravitational potential theory. Interestingly, the framework, dubbed EMOND, is able to reproduce the observed mass discrepancies in both galaxies and galaxy clusters, and to produce multi-center systems with offsets between the peaks of gravity and the peaks of the baryonic distribution.PACS numbers: 98.10.+z, 98.62.Dm, 95.35.+d, 95.30.Sf

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Substructure lensing in galaxy clusters as a constraint on low-mass sterile neutrinos in tensor-vector-scalar theory: The straight arc of Abell 2390

Cited by 13 publications

References 140 publications

The Acceleration Scale, Modified Newtonian Dynamics, and Sterile Neutrinos

The Acceleration Scale, Modified Newtonian Dynamics, and Sterile Neutrinos

Modified Newtonian Dynamics (MOND): Observational Phenomenology and Relativistic Extensions

Unifying all mass discrepancies with one effective gravity law?

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