Marit Sandstad’s research while affiliated with KTH Royal Institute of Technology and other places

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Publications (20)


Uncertainties in primordial black-hole constraints on the primordial power spectrum
  • Article

March 2018

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19 Reads

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23 Citations

Physics of the Dark Universe

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Florian Kuhnel

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Marit Sandstad

The existence (and abundance) of primordial black holes (PBHs) is governed by the power spectrum of primordial perturbations generated during inflation. So far no PBHs have been observed, and instead, increasingly stringent bounds on their existence at different scales have been obtained. Up until recently, this has been exploited in attempts to constrain parts of the inflationary power spectrum that are unconstrained by cosmological observations. We first point out that the simple translation of the PBH non-observation bounds into constraints on the primordial power spectrum is inaccurate as it fails to include realistic aspects of PBH formation and evolution. We then demonstrate, by studying two examples of uncertainties from the effects of critical and non-spherical collapse, that even though they may seem small, they have important implications for the usefulness of the constraints. In particular, we point out that the uncertainty induced by non-spherical collapse may be much larger than the difference between particular bounds from PBH non-observations and the general maximum cap stemming from the condition Ω≤1 on the dark-matter density in the form of PBHs. We therefore make the cautious suggestion of applying only the overall maximum dark-matter constraint to models of early Universe, as this requirement seems to currently provide a more reliable constraint, which better reflects our current lack of detailed knowledge of PBH formation. These, and other effects, such as merging, clustering and accretion, may also loosen constraints from non-observations of other primordial compact objects such as ultra-compact minihalos of dark matter.


On the covariance of teleparallel gravity theories
  • Article
  • Publisher preview available

July 2017

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48 Reads

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254 Citations

The basics of teleparallel gravity and its extensions are reviewed with particular emphasis on the problem of the Lorentz-breaking choice of connection in pure-tetrad versions of the theories. Various possible ways to covariantise such models are discussed. A by-product is a new form of f (T) field equations.

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FIG. 1: Would-be power-spectrum constraints (blue, solid curve) from non-observations of PBHs obtained from inverting Eq. (1). These constraints are taken from Ref. [16], but for easier comparison with Ref. [21] constraints from the Eridanus II cluster [52] and the CMB [53] have been excluded. The red, dotted line depicts an inversion according to Eq. (1) of the constraints that stem exclusively from the basic requirement Ω ≤ 1. The green, dot-dashed curve shows the power spectrum of the running-mass model described in the main text.
FIG. 2: Would-be power-spectrum constraints (blue, solid curve) from non-observations of PBHs obtained from inverting Eq. (1). These are the same as in Fig. 1. The black, dashed curve shows how these constraints will be weakened with a maximal hypothesis of non-sphericity effects in Eq. (4). Also shown (red, dotted line) is the Ω ≤ 1 constraint. Note that the latter lies below the former over the entire depicted mass range.
Primordial black holes do not (yet) constrain the primordial power spectrum

November 2016

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20 Reads

Primordial black holes (PBHs) are thought to have formed from extremely overdense regions that reentered the horizon after the end of inflation if there was sufficient power in primordial perturbations on specific scales. The existence (and abundance) of PBHs is therefore governed by the inflationary power spectrum. So far no primordial black holes have been observed, and instead, increasingly stringent bounds on their existence at different scales have been set. Up until recently this has been exploited in attempts to constrain parts of the inflationary power spectrum that are unconstrained by the cosmic microwave background and other cosmological observations. In this letter we point out that this simple translation of the PBH constraints into constraints on the primordial power spectrum is inaccurate as it fails to take into account realistic aspects of the PBH formation and evolution process. We show this by displaying a concrete example of a power spectrum that is seemingly in conflict with the constraints imposed on the power spectrum, but, when subjected to the well-studied critical-collapse effect, leads to a mass spectrum which is allowed by the PBH non-observations used to constrain the same power spectrum.


Primordial Black Holes as Dark Matter

July 2016

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82 Reads

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1,228 Citations

Physical Review D

The possibility that the dark matter comprises primordial black holes (PBHs) is considered, with particular emphasis on the currently allowed mass windows at 101610^{16} - 101710^{17}\,g, 102010^{20} - 102410^{24}\,g and 1 - 103M10^{3}\,M_{\odot}. The Planck mass relics of smaller evaporating PBHs are also considered. All relevant constraints (lensing, dynamical, large-scale structure and accretion) are reviewed and various effects necessary for a precise calculation of the PBH abundance (non-Gaussianity, non-sphericity, critical collapse and merging) are accounted for. It is difficult to put all the dark matter in PBHs if their mass function is monochromatic but this is still possible if the mass function is extended, as expected in many scenarios. A novel procedure for confronting observational constraints with an extended PBH mass spectrum is therefore introduced. This applies for arbitrary constraints and a wide range of PBH formation models, and allows us to identify which model-independent conclusions can be drawn from constraints over all mass ranges. We focus particularly on PBHs generated by inflation, pointing out which effects in the formation process influence the mapping from the inflationary power spectrum to the PBH mass function. We then apply our scheme to two specific inflationary models in which PBHs provide the dark matter. The possibility that the dark matter is in intermediate mass PBHs of 1 - 103M10^{3}\,M_{\odot} is of special interest in view of the recent detection of black hole mergers by LIGO. The possibility of Planck relics is also intriguing but virtually untestable.


Primordial Black Holes as Dark Matter

July 2016

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1 Citation

The possibility that the dark matter comprises primordial black holes (PBHs) is considered, with particular emphasis on the currently allowed mass windows at 101610^{16} - 101710^{17}\,g, 102010^{20} - 102410^{24}\,g and 1 - 103M10^{3}\,M_{\odot}. The Planck mass relics of smaller evaporating PBHs are also considered. All relevant constraints (lensing, dynamical, large-scale structure and accretion) are reviewed and various effects necessary for a precise calculation of the PBH abundance (non-Gaussianity, non-sphericity, critical collapse and merging) are accounted for. It is difficult to put all the dark matter in PBHs if their mass function is monochromatic but this is still possible if the mass function is extended, as expected in many scenarios. A novel procedure for confronting observational constraints with an extended PBH mass spectrum is therefore introduced. This applies for arbitrary constraints and a wide range of PBH formation models, and allows us to identify which model-independent conclusions can be drawn from constraints over all mass ranges. We focus particularly on PBHs generated by inflation, pointing out which effects in the formation process influence the mapping from the inflationary power spectrum to the PBH mass function. We then apply our scheme to two specific inflationary models in which PBHs provide the dark matter. The possibility that the dark matter is in intermediate-mass PBHs of 1 - 103M10^{3}\,M_{\odot} is of special interest in view of the recent detection of black-hole mergers by LIGO. The possibility of Planck relics is also intriguing but virtually untestable.


On Ellipsoidal Collapse and Primordial Black-Hole Formation

February 2016

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18 Reads

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47 Citations

Physical Review D

We reinvestigate gravitational ellipsoidal collapse with special focus on its impact on primordial black hole formation. We start with the results for the collapse threshold in the case of ellipsoidal collapse in the context of structure formation, and show heuristically that a similar functional form for the threshold should be expected in the case of primordial black hole formation. For a generic model we apply this to demonstrate that the abundance and energy density of the produced primordial black holes can be significantly decreased when the nonsphericity of the overdensities is taken into account. Further numerical study of this phenomenon may be crucial in order to produce reliable predictions for primordial black hole abundances from inflationary models.



Effects of Critical Collapse on Primordial Black-Hole Mass Spectra

December 2015

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227 Reads

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84 Citations

The European Physical Journal C

Certain inflationary models as well as realisations of phase transitions in the early Universe predict the formation of primordial black holes. For most mass ranges, the fraction of matter in the form of primordial black holes is limited by many different observations on various scales. Primordial black holes are assumed to be formed when overdensities that cross the horizon have Schwarzschild radii larger than the horizon. Traditionally it was therefore assumed that primordial black-hole masses were equal to the horizon mass at their time of formation. However, detailed calculations of their collapse show that primordial black holes formed at each point in time should rather form a spectrum of different masses, obeying critical scaling. Though this has been known for more than fifteen years, the effect of this scaling behaviour is largely ignored when considering predictions for primordial black hole mass spectra. In this paper we consider the critical collapse scaling for a variety of models which produce primordial black holes, and find that it generally leads to a shift, broadening and an overall decrease of the mass contained in primordial black holes. This effect is model and parameter dependent and cannot be contained by a constant rescaling of the spectrum; it can become extremely important and should be taken into account when comparing to observational constraints.


Effects of Critical Collapse on Primordial Black-Hole Mass Spectra

December 2015

Certain inflationary models as well as realisations of phase transitions in the early Universe predict the formation of primordial black holes. For most mass ranges, the fraction of matter in the form of primordial black holes is limited by many different observations on various scales. Primordial black holes are assumed to be formed when overdensities that cross the horizon have Schwarzschild radii larger than the horizon. Traditionally it was therefore assumed that primordial black-hole masses were equal to the horizon mass at their time of formation. However, detailed calculations of their collapse show that primordial black holes formed at each point in time should rather form a spectrum of different masses, obeying critical scaling. Though this has been known for more than fifteen years, the effect of this scaling behaviour is largely ignored when considering predictions for primordial black hole mass spectra. In this paper we consider the critical collapse scaling for a variety of models which produce primordial black holes, and find that it generally leads to a shift, broadening and an overall decrease of the mass contained in primordial black holes. This effect is model and parameter dependent and cannot be contained by a constant rescaling of the spectrum; it can become important and should be taken into account when comparing to observational constraints.


Citations (15)


... As discussed in refs. [61,62], when considering the non-sphericity of the overdensities, the abundance of the resulting PBHs experiences a notable reduction. In this case, the absence of detailed numerical simulations supporting these findings currently prevents us from drawing more quantitative conclusions. ...

Reference:

On the inflationary interpretation of the nHz gravitational-wave background
Uncertainties in primordial black-hole constraints on the primordial power spectrum
  • Citing Article
  • March 2018

Physics of the Dark Universe

... Recently [42], it was shown that local Lorentz invariance can be restored in modified teleparallel theories, if we start from a more general formulation of teleparallel gravity [43][44][45][46][47][48][49][50], in which teleparallelism is defined by a condition of vanishing curvature. This introduces the purely inertial spin connection to the theory that can be calculated consistently in the ordinary teleparallel gravity [48,49]. ...

On covariantisation of teleparallel gravity

... The consistency of this approach is encoded in the slow-roll parameters [2], which express conditions on the potential to support this motion. More recently, ultra slow-roll (USR) inflation has become increasingly popular as a mechanism for enhancing the peak in the primordial power spectrum, which can in turn facilitate the formation of primordial black holes (PBH) that can then contribute to the dark matter budget [3]. In USR, the potential driving term is assumed negligible and instead the scalar exponentially decelerates from Hubble friction. ...

Primordial Black Holes as Dark Matter
  • Citing Article
  • July 2016

Physical Review D

... The shapes of the peaks, including their height, ellipticity, and oblateness, can also be calculated accurately [34]. Since for the rare event of PBH formation non-sphericity can be safely neglected (see, e.g., [37,[55][56][57])), one can focus on analyzing the height and width of spherical peaks. Additionally, peaks theory provides the number density of maxima for any Gaussian random field based on its multiple moments, which are derived from the power spectrum. ...

On Ellipsoidal Collapse and Primordial Black-Hole Formation
  • Citing Article
  • February 2016

Physical Review D

... Therefore, the flux resulting from their evaporation and reaching us today is given by the redshifted sum of the contributions from all evaporating PBHs in our Universe, and can be used to constrain the average extragalactic distribution of DM in the form of PBHs. Furthermore, we work within the (also commonly adopted) approximation of monochromatic mass distributions (which can be expected if the formation mechanism arises from an amplification of the power spectrum at a very specific scale), although the effect of extended mass distributions is the subject of active research [343][344][345][346][347][348][349][350][351][352][353][354][355][356][357]. Finally, as discussed earlier, we only consider the primary photon contribution, as the secondary component resulting from the decay into photons of other unstable particles is verified a posteriori to be negligible given the mass range of interest. ...

Effects of Critical Collapse on Primordial Black-Hole Mass Spectra

The European Physical Journal C

... Comme l'illustre la Fig. 2.15, un trou noir virtuel peut absorber un proton et s'évaporer par radiation de Hawking [280][281][282]. Cependant, les modèles microscopiques de trous noirs, où ces derniers sont décrits comme des condensats de Bose-Einstein de gravitons [283,284], prédisent que les trous noirs peuvent avoir des charges globales [285,286]. Dans ces modèles, les arguments impliquant le théorème de calvitie, basés sur la relativité générale, sont alors valables dans la limite semi-classique idéale, que ne vérifie jamais un trou noir dans la Nature. ...

Baryon number conservation in Bose-Einstein condensate black holes
  • Citing Article
  • June 2015

Physical Review D