X-ray cluster constraints on non-Gaussianity

Sarah Shandera; Adam Mantz; Steven W. Allen; David Angelo Rapetti Serra

doi:10.1088/1475-7516/2013/08/004

X-ray cluster constraints on non-Gaussianity

Sarah Shandera, Adam Mantz, Steven W. Allen, David Angelo Rapetti Serra

DARK

13 Citations (Scopus)

Abstract

We report constraints on primordial non-Gaussianity from the abundance of X-ray detected clusters. Our analytic prescription for adding non-Gaussianity to the cluster mass function takes into account moments beyond the skewness, and we demonstrate that those moments should not be ignored in most analyses of cluster data. We constrain the amplitude of the skewness for two scenarios that have different overall levels of non-Gaussianity, characterized by how amplitudes of higher cumulants scale with the skewness. We find that current data can constrain these one-parameter non-Gaussian models at a useful level, but are not sensitive to adding further details of the corresponding inflation scenarios. Combining cluster data with Cosmic Microwave Background constraints on the cosmology and power spectrum amplitude, we find the dimensionless skewness to be 10³3 = -1-28⁺²⁴ for one of our scaling scenarios, and 10³3 = -4±7 for the other. These are the first constraints on non-Gaussianity from Large Scale Structure that can be usefully applied to any model of primordial non-Gaussianity. The former constraint, when applied to the standard local ansatz (where the n-th cumulant scales as n3 ^n-2), corresponds to fNL^local = -3-91⁺⁷⁸. When applied to a model with a local-shape bispectrum but higher cumulants that scale as n3^n/3 (the second scaling scenario), the amplitude of the local-shape bispectrum is constrained to be fNL^local* = -14-21⁺²². For this second scaling (which occurs in various well-motivated models of inflation), we also obtain strong constraints on the equilateral and orthogonal shapes of the bispectrum, fNL^equil = -52-79⁺⁸⁵ and fNL^orth = 63-104⁺⁹⁷. This sensitivity implies that cluster counts could be used to distinguish qualitatively different models for the primordial fluctuations that have identical bispectra.

Original language	English
Article number	004
Journal	Journal of Cosmology and Astroparticle Physics
Volume	2013
Issue number	8
ISSN	1475-7516
DOIs	https://doi.org/10.1088/1475-7516/2013/08/004
Publication status	Published - 1 Aug 2013

Access to Document

10.1088/1475-7516/2013/08/004

Cite this

@article{b7ec0a12da5f401d877a4dff7f7cacfa,

title = "X-ray cluster constraints on non-Gaussianity",

abstract = "We report constraints on primordial non-Gaussianity from the abundance of X-ray detected clusters. Our analytic prescription for adding non-Gaussianity to the cluster mass function takes into account moments beyond the skewness, and we demonstrate that those moments should not be ignored in most analyses of cluster data. We constrain the amplitude of the skewness for two scenarios that have different overall levels of non-Gaussianity, characterized by how amplitudes of higher cumulants scale with the skewness. We find that current data can constrain these one-parameter non-Gaussian models at a useful level, but are not sensitive to adding further details of the corresponding inflation scenarios. Combining cluster data with Cosmic Microwave Background constraints on the cosmology and power spectrum amplitude, we find the dimensionless skewness to be 1033 = -1-28+24 for one of our scaling scenarios, and 1033 = -4±7 for the other. These are the first constraints on non-Gaussianity from Large Scale Structure that can be usefully applied to any model of primordial non-Gaussianity. The former constraint, when applied to the standard local ansatz (where the n-th cumulant scales as n3 n-2), corresponds to fNLlocal = -3-91+78. When applied to a model with a local-shape bispectrum but higher cumulants that scale as n3n/3 (the second scaling scenario), the amplitude of the local-shape bispectrum is constrained to be fNLlocal* = -14-21+22. For this second scaling (which occurs in various well-motivated models of inflation), we also obtain strong constraints on the equilateral and orthogonal shapes of the bispectrum, fNLequil = -52-79+85 and fNLorth = 63-104+97. This sensitivity implies that cluster counts could be used to distinguish qualitatively different models for the primordial fluctuations that have identical bispectra.",

author = "Sarah Shandera and Adam Mantz and Allen, {Steven W.} and {Rapetti Serra}, {David Angelo}",

year = "2013",

month = aug,

day = "1",

doi = "10.1088/1475-7516/2013/08/004",

language = "English",

volume = "2013",

journal = "Journal of Cosmology and Astroparticle Physics",

issn = "1475-7516",

publisher = "IOP Publishing",

number = "8",

}

TY - JOUR

T1 - X-ray cluster constraints on non-Gaussianity

AU - Shandera, Sarah

AU - Mantz, Adam

AU - Allen, Steven W.

AU - Rapetti Serra, David Angelo

PY - 2013/8/1

Y1 - 2013/8/1

N2 - We report constraints on primordial non-Gaussianity from the abundance of X-ray detected clusters. Our analytic prescription for adding non-Gaussianity to the cluster mass function takes into account moments beyond the skewness, and we demonstrate that those moments should not be ignored in most analyses of cluster data. We constrain the amplitude of the skewness for two scenarios that have different overall levels of non-Gaussianity, characterized by how amplitudes of higher cumulants scale with the skewness. We find that current data can constrain these one-parameter non-Gaussian models at a useful level, but are not sensitive to adding further details of the corresponding inflation scenarios. Combining cluster data with Cosmic Microwave Background constraints on the cosmology and power spectrum amplitude, we find the dimensionless skewness to be 1033 = -1-28+24 for one of our scaling scenarios, and 1033 = -4±7 for the other. These are the first constraints on non-Gaussianity from Large Scale Structure that can be usefully applied to any model of primordial non-Gaussianity. The former constraint, when applied to the standard local ansatz (where the n-th cumulant scales as n3 n-2), corresponds to fNLlocal = -3-91+78. When applied to a model with a local-shape bispectrum but higher cumulants that scale as n3n/3 (the second scaling scenario), the amplitude of the local-shape bispectrum is constrained to be fNLlocal* = -14-21+22. For this second scaling (which occurs in various well-motivated models of inflation), we also obtain strong constraints on the equilateral and orthogonal shapes of the bispectrum, fNLequil = -52-79+85 and fNLorth = 63-104+97. This sensitivity implies that cluster counts could be used to distinguish qualitatively different models for the primordial fluctuations that have identical bispectra.

AB - We report constraints on primordial non-Gaussianity from the abundance of X-ray detected clusters. Our analytic prescription for adding non-Gaussianity to the cluster mass function takes into account moments beyond the skewness, and we demonstrate that those moments should not be ignored in most analyses of cluster data. We constrain the amplitude of the skewness for two scenarios that have different overall levels of non-Gaussianity, characterized by how amplitudes of higher cumulants scale with the skewness. We find that current data can constrain these one-parameter non-Gaussian models at a useful level, but are not sensitive to adding further details of the corresponding inflation scenarios. Combining cluster data with Cosmic Microwave Background constraints on the cosmology and power spectrum amplitude, we find the dimensionless skewness to be 1033 = -1-28+24 for one of our scaling scenarios, and 1033 = -4±7 for the other. These are the first constraints on non-Gaussianity from Large Scale Structure that can be usefully applied to any model of primordial non-Gaussianity. The former constraint, when applied to the standard local ansatz (where the n-th cumulant scales as n3 n-2), corresponds to fNLlocal = -3-91+78. When applied to a model with a local-shape bispectrum but higher cumulants that scale as n3n/3 (the second scaling scenario), the amplitude of the local-shape bispectrum is constrained to be fNLlocal* = -14-21+22. For this second scaling (which occurs in various well-motivated models of inflation), we also obtain strong constraints on the equilateral and orthogonal shapes of the bispectrum, fNLequil = -52-79+85 and fNLorth = 63-104+97. This sensitivity implies that cluster counts could be used to distinguish qualitatively different models for the primordial fluctuations that have identical bispectra.

U2 - 10.1088/1475-7516/2013/08/004

DO - 10.1088/1475-7516/2013/08/004

M3 - Journal article

SN - 1475-7516

VL - 2013

JO - Journal of Cosmology and Astroparticle Physics

JF - Journal of Cosmology and Astroparticle Physics

IS - 8

M1 - 004

ER -

X-ray cluster constraints on non-Gaussianity

Abstract

Access to Document

Fingerprint

Cite this