Model-independent constraints on cosmic curvature: implication from updated Hubble diagram of high-redshift standard candles

Abstract

The cosmic curvature (k) is a fundamental parameter for cosmology. In this paper, we propose an improved model-independent method to constrain the cosmic curvature, which is geometrically related to the Hubble parameter H(z) and luminosity distance DL(z). Using the currently largest H(z) sample from the well-known cosmic chronometers, as well as the luminosity distance DL(z) from the relation between the UV and X-ray luminosities of 1598 quasars and the newly-compiled Pantheon sample including 1048 SNe Ia, 31 independent measurements of the cosmic curvature k(z) can be expected covering the redshift range of 0.07<z<2. Our estimation of k(z) is fully compatible with flat Universe at the current level of observational precision. Meanwhile, we find that, for the Hubble diagram of 1598 quasars as a new type of standard candle, the spatial curvature is constrained to be k=0.080.31. For the latest Pantheon sample of SNe Ia observations, we obtain k= -0.020.14. Compared to other approaches aiming for model-independent estimations of spatial curvature, our analysis also achieves constraints with competitive precision. More interestingly, it is suggested that the reconstructed curvature k is negative in the high redshift region, which is also consistent with the results from the model-dependent constraints in the literature. Such findings are confirmed by our reconstructed evolution of k(z), in the framework of a model-independent method of Gaussian processes (GP) without assuming a specific form.