Is the Universe transparent?

Liao, Kai; Avgoustidis, Anastasios; Li, Zheng‐Xiang

doi:10.1103/physrevd.92.123539

Cited by 45 publications

(55 citation statements)

References 44 publications

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“…The results, in the framework of three model-independent methods (nearby SNe Ia method, interpolation method and smoothing method), converged to a point that the effects of cosmic opacity are vanished. Such methodology was recently extended by Liao et al [25], who examined the residuals between the constructed opacity-free luminosity distances from H(z) determinations and distance estimation in type Ia supernovae observations with variable light-curve fitting parameters. A transparent universe is currently consistent with the current EM data.…”

Section: Cosmic Opacity Parameterizations and Constraintsmentioning

confidence: 99%

“…More recently, some substantial progress has been made in the measurements of the Hubble parameter H(z), which are combined with different sub-samples of SNe Ia observations to quantify the cosmic opacity [23,24]. However, it is worth noting that H(z) describes the expansion rate of the universe rather than the distance, i.e., the angular diameter distance obtained by integrating these scattered points will inevitably lead to large uncertainties, which indicated the importance of taking the correlations between different redshifts into account [25]. More importantly, considering the limited sample size of H(z) measurements, one has also to take care of the errors due to the mismatch between the H(z) redshift and the closest SNe Ia in the companion SNe Ia sample adopted.…”

Section: Introductionmentioning

confidence: 99%

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Cosmic opacity: Cosmological-model-independent tests from gravitational waves and Type Ia Supernova

Cao

Pan

et al. 2019

Physics of the Dark Universe

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In this paper, we present a scheme to investigate the opacity of the Universe in a cosmologicalmodel-independent way, with the combination of current and future available data in gravitational wave (GW) and electromagnetic (EM) domain. In the FLRW metric, GWs propagate freely through a perfect fluid without any absorption and dissipation, which provides a distance measurement unaffected by the cosmic opacity. Focusing on the simulated data of gravitational waves from the third-generation gravitational wave detector (the Einstein Telescope, ET), as well as the newlycompiled SNe Ia data (JLA and Pantheon sample), we find an almost transparent universe is strongly favored at much higher redshifts (z ∼ 2.26). Our results suggest that, although the tests of cosmic opacity are not significantly sensitive to its parametrization, a strong degeneracy between the cosmic opacity parameter and the absolute B -band magnitude of SNe Ia is revealed in this analysis. More importantly, we obtain that future measurements of the luminosity distances of gravitational waves sources will be much more competitive than the current analyses, which makes it expectable more vigorous and convincing constraints on the cosmic opacity (and consequently on background physical mechanisms) and a deeper understanding of the intrinsic properties of type Ia supernovae in a cosmological-model-independent way.

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Section: Cosmic Opacity Parameterizations and Constraintsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Cosmic opacity: Cosmological-model-independent tests from gravitational waves and Type Ia Supernova

Cao

Pan

et al. 2019

Physics of the Dark Universe

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“…Holanda et al [85] parametrized the redshift dependence of η(z) in two distinct forms, η(z) = 1 + η 0 z(P1) and η(z) = 1 + η 0 z/(1 + z)(P2) and investigated the η 0 parameter by employing the luminosity distance D L measurements from Type Ia supernovae (SNe Ia) and diameter distance D A from galaxy clusters [86,87]. Several other authors have also tested the DDR relation using different observations: SNe Ia plus cosmic microwave background (CMB) and barion acoustic oscillations (BAO) [88], SNe Ia plus H(z) data [77,[89][90][91], gas mass fraction of galaxy clusters and SNe Ia [92,93], CMB spectrum [94], gammaray burst (GRB) plus H(z) [95], SNe Ia plus BAO [96], gas mass fraction plus H(z) [97], gravitational lensing plus SNe Ia [98], SNe Ia and radio galaxy plus CMB [99]. Most of the above authors obtain no significant deviation in DDR relation, although, roughly the scatter in η 0 parameter is observed as ±0.1 to ±0.…”

Section: Methodsmentioning

confidence: 99%

Constraining axionlike particles using the distance-duality relation

Tiwari¹

2017

Phys. Rev. D

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One of the fundamental results used in observational cosmology is the distance duality relation (DDR), which relates the luminosity distance, DL, with angular diameter distance, DA, at a given redshift z. We employ the observed limits of this relation to constrain the coupling of axion like particles (ALPs) with photons. With our detailed 3D ALP-photon mixing simulation in standard ΛCDM universe and latest DDR limits observed in Holand & Barros (2016) we limit the coupling constant g φ ≤ 6 × 10 −13 GeV −1 nG B Mpc for ALPs of mass ≤ 10 −15 eV. The DDR observations can provide very stringent constraint on ALPs mixing in future. Also any deviation in DDR can be conventionally explained as photons decaying to axions or vice-versa.

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“…Clusters × Union2.1 (B) [44] 0.009± 0.059 0.055 0.014± 0.071 0.069 H(z) × Union2.1(B) [42] −0.01 ± 0.10 −0.01 ± 0.12 H(z)× JLA (B) [43] 0.07± 0.107 0.121 ages of old objects × Union2.1 (B) [40] 0.016± 0.078…”

Section: 18mentioning

confidence: 99%

Probing the cosmic opacity from future gravitational wave standard sirens

Zhou¹,

Peng³

2019

Phys. Rev. D

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In this work, using the Gaussian Process, we explore the potentiality of future gravitational wave (GW) measurement to probe cosmic opacity through comparing its opacity-free luminosity distance (LD) with the opacity-dependent one from type Ia supernovae (SNIa). GW data points are simulated from the third generation Einstein Telescope, and SNIa data are taken from the Joint Light Analysis (JLA) or Pantheon compilation. The advantages of using Gaussian Process are that one may match SNIa data with GW data at the same redshift and use all available data to probe cosmic opacity. We obtain that the error bar of the constraint on cosmic opacity can be reduced to σ ǫ ∼ 0.011 and 0.006 at 1σ confidence level (CL) for JLA and Pantheon respectively in a cosmological-independent way. Thus, the future GW measurements can give competitive results on the cosmic opacity test. Furthermore, we propose a method to probe the spatial homogeneity of the cosmic transparency through comparing the reconstructed LD from the mock GW with the reconstructed one from SNIa data in a flat ΛCDM with the Gaussian Process. The result shows that a transparent universe is favored at 1σ CL, although the best-fit value of cosmic opacity is redshift-dependent.

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Is the Universe transparent?

Cited by 45 publications

References 44 publications

Cosmic opacity: Cosmological-model-independent tests from gravitational waves and Type Ia Supernova

Cosmic opacity: Cosmological-model-independent tests from gravitational waves and Type Ia Supernova

Constraining axionlike particles using the distance-duality relation

Probing the cosmic opacity from future gravitational wave standard sirens

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