Approximation methods for non-linear gravitational clustering

Sahni, Varun; Coles, Peter

doi:10.1016/0370-1573(95)00014-8

Cited by 190 publications

(239 citation statements)

References 482 publications

(1,009 reference statements)

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“…CDM-type spectra have the following approximate form of the transfer function [165,194,166] T (k) = 1 + Ak 2 log (1 + Bk)…”

Section: Dark Mattermentioning

confidence: 99%

“…(The precise location of the turn-around and the amplitude of P (k) depend upon specific details of the cosmological model, see for instance [16].) The 'standard' cold dark matter (SCDM) paradigm, which assumed that Ω CDM = 1, was introduced during the early 1980's at roughly the same time when HDM was perceived to be in trouble (see [101,96,50,166] for references to earlier work on this subject). Although SCDM was very successful in explaining a host of observational details, it was clear already a decade ago, that the processed power spectrum of SCDM lacked sufficient power on large scales and so fell short of explaining the angular two point correlation function for galaxies on scales ∼ 50 Mpc [60].…”

Section: Dark Mattermentioning

confidence: 99%

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5 Dark Matter and Dark Energy

Sahni¹

2004

Lecture Notes in Physics

494

287

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Abstract. I briefly review our current understanding of dark matter and dark energy. The first part of this paper focusses on issues pertaining to dark matter including observational evidence for its existence, current constraints and the 'abundance of substructure' and 'cuspy core' issues which arise in CDM. I also briefly describe MOND. The second part of this review focusses on dark energy. In this part I discuss the significance of the cosmological constant problem which leads to a predicted value of the cosmological constant which is almost 10 123 times larger than the observed value Λ/8πG ≃ 10 −47 GeV 4 . Setting Λ to this small value ensures that the acceleration of the universe is a fairly recent phenomenon giving rise to the 'cosmic coincidence' conundrum according to which we live during a special epoch when the density in matter and Λ are almost equal. Anthropic arguments are briefly discussed but more emphasis is placed upon dynamical dark energy models in which the equation of state is time dependent. These include Quintessence, Braneworld models, Chaplygin gas and Phantom energy. Model independent methods to determine the cosmic equation of state and the Statefinder diagnostic are also discussed. The Statefinder has the attractive property ... a /aH 3 = 1 for LCDM, which is helpful for differentiating between LCDM and rival dark energy models. The review ends with a brief discussion of the fate of the universe in dark energy models.

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“…CDM-type spectra have the following approximate form of the transfer function [165,194,166] T (k) = 1 + Ak 2 log (1 + Bk)…”

Section: Dark Mattermentioning

confidence: 99%

Section: Dark Mattermentioning

confidence: 99%

5 Dark Matter and Dark Energy

Sahni¹

2004

Lecture Notes in Physics

494

287

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“…That condition is obeyed with a high accuracy well before the matter/radiation equality. In particular, this guarantees that IDM is indistinguishable from CDM at the level of cosmic microwave background measurements 6 .…”

Section: Introductionmentioning

confidence: 92%

Initial conditions for imperfect dark matter

Ramazanov¹

2015

J. Cosmol. Astropart. Phys.

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“…Even the simplest of these (Lagrangian) approaches, the Zeldovich approximation (Zeldovich 1970), has proved highly successful in comparison against full N-body calculations in describing the quantitative morphology of the clustering pattern (Coles et al 1993). For a review of both these approaches, see Sahni and Coles (1995).…”

Section: Introductionmentioning

confidence: 99%

Gravitational instability via the Schrödinger equation

Short¹,

Coles²

2006

J. Cosmol. Astropart. Phys.

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Abstract. We study an approach to the formation of large-scale structure in the universe based on the description of a self-gravitating fluid in terms of a Schrödinger equation coupled to the usual Poisson equation. This approach has a number of promising features, but also some peculiarities. In this exploratory paper we discuss the behaviour of perturbations of the Schrödinger-Poisson system in simple one-dimensional configurations and compare the results with more conventional approaches: linear perturbation theory of the fluid equations and the Zeldovich approximation. The results demonstrate that our approach furnishes a useful addition to the repertoire of analytical techniques available for the description of cosmological perturbations, but that there are a number of subtleties to be faced when this method is applied in practice. In particular, care must be taken in choosing appropriate values for the effective Planck constant in the theory.PACS numbers: 95.35.+d, 98.65.Dx, Submitted to: J. Cosmol. Astropart. Phys.

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Approximation methods for non-linear gravitational clustering

Cited by 190 publications

References 482 publications

5 Dark Matter and Dark Energy

5 Dark Matter and Dark Energy

Initial conditions for imperfect dark matter

Gravitational instability via the Schrödinger equation

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