Constraints on anisotropic cosmic expansion from supernovae

Kalus, Benedict; Schwarz, Dominik J.; Seikel, Marina; Wiegand, Alexander

doi:10.1051/0004-6361/201220928

Cited by 98 publications

(121 citation statements)

References 44 publications

(61 reference statements)

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“…Although there is still some debate [34][35][36], it has been claimed that these preferred directions are also aligned with the CMB kinematic dipole and the preferred direction of CMB quadrupole and octopole [33]. If all the directional preferences would be confirmed in the future, it would imply that the underlying physical or systematic reasons of all the cosmological anomalies should be connected.…”

Section: Discussionmentioning

confidence: 99%

Directional dependence of CMB parity asymmetry

Zhao

2014

Phys. Rev. D

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Parity violation in the cosmic microwave background (CMB) radiation has been confirmed by recent Planck observation. In this paper, we extend our previous work [P. Naselsky et al. Astrophys. J. 749, 31 (2012)] on the directional properties of CMB parity asymmetry by considering the Planck data of the CMB temperature anisotropy. We define six kinds of the directional statistics and find that they all indicate the odd-parity preference of CMB data. In addition, we find the preferred axes of all these statistics strongly correlate with the preferred axes of the CMB kinematic dipole, quadrupole, and octopole. The alignment between them is confirmed at more than 3σ confidence level, which implies that the CMB parity asymmetry, and the anomalies of the CMB quadrupole and octopole, may have the common physical, contaminated or systematic origin. In addition, they all should be connected with the possible contamination of the residual dipole component. PACS numbers: 95.85.Sz, 98.70.Vc, 98.80.Cq *

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Section: Discussionmentioning

confidence: 99%

Directional dependence of CMB parity asymmetry

Zhao

2014

Phys. Rev. D

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“…It is crucial then to theoretically predict these effects at the level of precision required by upcoming observations. Current theoretical works rely on analytical calculations based on either linear perturbation theory or its modifications that include some nonlinear effects (Wang et al 1998;Cooray & Caldwell 2006;Li & Schwarz 2008;Wiegand & Schwarz 2012;Kalus et al 2013;Marra et al 2013). Although this approach can give valid initial insights, it is insufficient for taking into account all non-linear effects and therefore to provide accurate predictions for the next generation measurements.…”

Section: Introductionmentioning

confidence: 99%

Cosmic variance of the local Hubble flow in large-scale cosmological simulations

Wojtak¹,

Knebe²,

Watson³

et al. 2013

Monthly Notices of the Royal Astronomical Society

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The increasing precision in the determination of the Hubble parameter has reached a per cent level at which large-scale cosmic flows induced by inhomogeneities of the matter distribution become non-negligible. Here we use large-scale cosmological Nbody simulations to study statistical properties of the local Hubble parameter as measured by local observers. We show that the distribution of the local Hubble parameter depends not only on the scale of inhomogeneities, but also on how one defines the positions of observers in the cosmic web and what reference frame is used. Observers located in random dark matter haloes measure on average lower expansion rates than those at random positions in space or in the centres of cosmic voids, and this effect is stronger from the halo rest frames compared to the CMB rest frame. We compare the predictions for the local Hubble parameter with observational constraints based on type Ia supernovae (SNIa) and CMB observations. Due to cosmic variance, for observers located in random haloes we show that the Hubble constant determined from nearby SNIa may differ from that measured from the CMB by ±0.8 per cent at 1σ statistical significance. This scatter is too small to significantly alleviate a recently claimed discrepancy between current measurements assuming a flat ΛCDM model. However, for observers located in the centres of the largest voids permitted by the standard ΛCDM model, we find that Hubble constant measurements from SNIa would be biased high by 5 per cent, rendering this tension inexistent in this extreme case.

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“…An alternative method is to analyze the SNe Ia data in a model-independent way (Antoniou & Perivolaropoulos 2010;Mariano & Perivolaropoulos 2012;Cai & Tuo 2012;Cai et al 2013;Kalus et al 2013;Zhang et al 2013;Yang et al 2014). The advantage of this method is that it does not rely on the particular cosmological model.…”

Section: Introductionmentioning

confidence: 99%

Comparison between hemisphere comparison method and dipole-fitting method in tracing the anisotropic expansion of the Universe use the Union2 data set

Chang

Lin

2014

Monthly Notices of the Royal Astronomical Society

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Type-Ia supernovae (SNe Ia) are often used as the standard candles to probe the anisotropic expansion of the Universe. In this paper, we make a comprehensive comparison between the hemisphere comparison (HC) method and dipole-fitting (DF) method in searching for the cosmological preferred direction using the Union2 dataset, a compilation of 557 well-calibrated SNe Ia. We find that the directions of the faintest SNe Ia derived from these two methods are approximately opposite. Monte Carlo simulations show that the results of the HC method strongly depend on the distribution of the data points in the sky. The coincidence that the HC method and DF method give two completely opposite directions may be due to the extremely nonuniform distribution of the Union2 dataset.

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Constraints on anisotropic cosmic expansion from supernovae

Cited by 98 publications

References 44 publications

Directional dependence of CMB parity asymmetry

Directional dependence of CMB parity asymmetry

Cosmic variance of the local Hubble flow in large-scale cosmological simulations

Comparison between hemisphere comparison method and dipole-fitting method in tracing the anisotropic expansion of the Universe use the Union2 data set

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