WIMPs and stellar-mass primordial black holes are incompatible

Adamek, Julian; Byrnes, Christian T.; Gosenca, Mateja; Hotchkiss, Shaun

doi:10.1103/physrevd.100.023506

Cited by 120 publications

(205 citation statements)

References 40 publications

(85 reference statements)

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“…(3.10)-(3.13), including in the geometry (expressed in GLC form) all contributions arising from the Bardeen potential ψ, up to first order. Following the procedure (and the results) of previous papers (see in particular [26], where similar computations have been performed by consistently including all second order perturbative contributions) we thus expand the coordinate transformation as y µ (x) = y µ (0) +y µ (1) +· · · , and linearize the perturbed GLC metric by defining Υ = Υ (0) +Υ (1) ,…”

Section: Comparing Different Averaging Prescriptionsmentioning

confidence: 99%

“…Here Φ F LRW is the unperturbed value of Φ computed in the FLRW metric background, and the corresponding fractional correction f Φ (z) is given by [21] f Φ (z) = δΦ (2) 0 + δµ (1) δΦ (1) 0 − δµ (1) 0 δΦ (1) 0 , (4.9)…”

Section: Example: Fractional Corrections To the Flux Averagementioning

confidence: 99%

“…where δµ (1) is the same term appearing in Eq. (4.9), arising from the perturbations of the measure (3.12).…”

Section: Example: Fractional Corrections To the Flux Averagementioning

confidence: 99%

“…For instance, the possible impact of small scale inhomogeneities on the large scale dynamics cannot be properly addressed without using a well-posed prescription for averaging their contribution to the cosmological equations. In addition, recent results in the context of numerical relativity have stressed the need for a full theoretical control on the choice of the averaging procedure [1]. Starting with the right choice is crucial for reaching the sought level of precision (or, more ambitiously, for writing the correct numerical code) in the context of modern cosmological simulations [2][3][4][5].…”

Section: Introductionmentioning

confidence: 99%

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Generalized covariant prescriptions for averaging cosmological observables

Fanizza

Gasperini

Marozzi

et al. 2020

J. Cosmol. Astropart. Phys.

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We present two new covariant and general prescriptions for averaging scalar observables on spatial regions typical of the observed sources and intersecting the past light-cone of a given observer. One of these prescriptions is adapted to sources exactly located on a given space-like hypersurface, the other applies instead to situations where the physical location of the sources is characterized by the experimental "spread" of a given observational variable. The geometrical and physical differences between the two procedures are illustrated by computing the averaged energy flux received by distant sources located on (or between) constant redshift surfaces, and by working in the context of a perturbed ΛCDM geometry. We find significant numerical differences (of about ten percent or more, in a large range of redshift) even limiting our model to scalar metric perturbations, and stopping our computations to the leading non-trivial perturbative order.

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Section: Comparing Different Averaging Prescriptionsmentioning

confidence: 99%

Section: Example: Fractional Corrections To the Flux Averagementioning

confidence: 99%

“…where δµ (1) is the same term appearing in Eq. (4.9), arising from the perturbations of the measure (3.12).…”

Section: Example: Fractional Corrections To the Flux Averagementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Generalized covariant prescriptions for averaging cosmological observables

Fanizza

Gasperini

Marozzi

et al. 2020

J. Cosmol. Astropart. Phys.

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show abstract

“…In such a mass range, there are already stringent bounds on the fraction of DM composed by PBHs, see for example [12]. Thus one is forced to consider the accretion onto PBHs in the presence of an additional DM component which forms a dark halo of mass M h , truncated at a radius r h given by (assuming a power law density profile ρ ∝ r −α , with approximately α 2.25) [53,54] which is plotted in Fig. 1 and obtained following the procedure reported in Appendix B, including the relevant estimate of the relative velocity v rel .…”

mentioning

confidence: 99%

The evolution of primordial black holes and their final observable spins

Luca

Franciolini

Pani

et al. 2020

J. Cosmol. Astropart. Phys.

122

173

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Primordial black holes in the mass range of ground-based gravitational-wave detectors can comprise a significant fraction of the dark matter. Mass and spin measurements from coalescences can be used to distinguish between an astrophysical or a primordial origin of the binary black holes. In standard scenarios the spin of primordial black holes is very small at formation. However, the mass and spin can evolve through the cosmic history due to accretion. We show that the mass and spin of primordial black holes are correlated in a redshift-dependent fashion, in particular primordial black holes with masses below O(30)M are likely non-spinning at any redshift, whereas heavier black holes can be nearly extremal up to redshift z ∼ 10. The dependence of the mass and spin distributions on the redshift can be probed with future detectors such as the Einstein Telescope. The mass and spin evolution affect the gravitational waveform parameters, in particular the distribution of the final mass and spin of the merger remnant, and that of the effective spin of the binary. We argue that, compared to the astrophysical-formation scenario, a primordial origin of black hole binaries might better explain the spin distribution of merger events detected by LIGO-Virgo, in which the effective spin parameter of the binary is compatible to zero except possibly for few high-mass events. Upcoming results from LIGO-Virgo third observation run might reinforce or weaken these predictions.

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Large-scale dark matter simulations

Angulo

Hahn

2022

Living Rev Comput Astrophys

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We review the field of collisionless numerical simulations for the large-scale structure of the Universe. We start by providing the main set of equations solved by these simulations and their connection with General Relativity. We then recap the relevant numerical approaches: discretization of the phase-space distribution (focusing on N-body but including alternatives, e.g., Lagrangian submanifold and Schrödinger–Poisson) and the respective techniques for their time evolution and force calculation (direct summation, mesh techniques, and hierarchical tree methods). We pay attention to the creation of initial conditions and the connection with Lagrangian Perturbation Theory. We then discuss the possible alternatives in terms of the micro-physical properties of dark matter (e.g., neutralinos, warm dark matter, QCD axions, Bose–Einstein condensates, and primordial black holes), and extensions to account for multiple fluids (baryons and neutrinos), primordial non-Gaussianity and modified gravity. We continue by discussing challenges involved in achieving highly accurate predictions. A key aspect of cosmological simulations is the connection to cosmological observables, we discuss various techniques in this regard: structure finding, galaxy formation and baryonic modelling, the creation of emulators and light-cones, and the role of machine learning. We finalise with a recount of state-of-the-art large-scale simulations and conclude with an outlook for the next decade.

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WIMPs and stellar-mass primordial black holes are incompatible

Cited by 120 publications

References 40 publications

Generalized covariant prescriptions for averaging cosmological observables

Generalized covariant prescriptions for averaging cosmological observables

The evolution of primordial black holes and their final observable spins

Large-scale dark matter simulations

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