An Improved Method to Measure the Cosmic Curvature

In this paper, we propose an improved model-independent method to constrain the cosmic curvature by combining the most recent Hubble parameter H(z) and supernovae Ia (SNe Ia) data. Based on the H(z) data, we first use the model-independent smoothing technique, Gaussian processes, to construct a dist...

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Veröffentlicht in:	The Astrophysical journal 2017-04, Vol.838 (2), p.160
Hauptverfasser:	Wei, Jun-Jie, Wu, Xue-Feng
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Sprache:	eng
Schlagworte:	Astrophysics ASTROPHYSICS, COSMOLOGY AND ASTRONOMY COMPARATIVE EVALUATIONS Confidence intervals cosmological parameters COSMOLOGY cosmology: observations Curvature Curve fitting DATA GALAXIES galaxies: general Gaussian process GAUSSIAN PROCESSES Hubble constant LIMITING VALUES Mathematical models Parameter estimation SUPERNOVAE supernovae: general UNIVERSE VISIBLE RADIATION
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description	In this paper, we propose an improved model-independent method to constrain the cosmic curvature by combining the most recent Hubble parameter H(z) and supernovae Ia (SNe Ia) data. Based on the H(z) data, we first use the model-independent smoothing technique, Gaussian processes, to construct a distance modulus H(z), which is susceptible to the cosmic curvature parameter k. In contrary to previous studies, the light-curve-fitting parameters, which account for the distance estimation of SN ( SN(z)), are set free to investigate whether k has a dependence on them. By comparing H(z) to SN(z), we put limits on k. Our results confirm that k is independent of the SN light-curve parameters. Moreover, we show that the measured k is in good agreement with zero cosmic curvature, implying that there is no significant deviation from a flat universe at the current observational data level. We also test the influence of different H(z) samples and different Hubble constant H0 values, finding that different H(z) samples do not have a significant impact on the constraints. However, different H0 priors can affect the constraints of k to some degree. The prior of H0 = 73.24 1.74 km s−1 Mpc−1 gives a value of k, a little bit above the 1 confidence level away from 0, but H0 = 69.6 0.7 km s−1 Mpc−1 gives it below 1 .
doi_str_mv	10.3847/1538-4357/aa674b
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J</addtitle><description>In this paper, we propose an improved model-independent method to constrain the cosmic curvature by combining the most recent Hubble parameter H(z) and supernovae Ia (SNe Ia) data. Based on the H(z) data, we first use the model-independent smoothing technique, Gaussian processes, to construct a distance modulus H(z), which is susceptible to the cosmic curvature parameter k. In contrary to previous studies, the light-curve-fitting parameters, which account for the distance estimation of SN ( SN(z)), are set free to investigate whether k has a dependence on them. By comparing H(z) to SN(z), we put limits on k. Our results confirm that k is independent of the SN light-curve parameters. Moreover, we show that the measured k is in good agreement with zero cosmic curvature, implying that there is no significant deviation from a flat universe at the current observational data level. We also test the influence of different H(z) samples and different Hubble constant H0 values, finding that different H(z) samples do not have a significant impact on the constraints. However, different H0 priors can affect the constraints of k to some degree. 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subjects	Astrophysics ASTROPHYSICS, COSMOLOGY AND ASTRONOMY COMPARATIVE EVALUATIONS Confidence intervals cosmological parameters COSMOLOGY cosmology: observations Curvature Curve fitting DATA GALAXIES galaxies: general Gaussian process GAUSSIAN PROCESSES Hubble constant LIMITING VALUES Mathematical models Parameter estimation SUPERNOVAE supernovae: general UNIVERSE VISIBLE RADIATION
title	An Improved Method to Measure the Cosmic Curvature
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