Affiliation:
1. Department of Applied Physics Delhi Technological University Delhi 110042 India
2. Department of Applied Mathematics Delhi Technological University Delhi 110042 India
3. Pacif Institute of Cosmology and Selfology (PICS) Sagara Sambalpur Odisha 768224 India
4. Department of Mathematics Shyamlal College, University of Delhi Delhi 110032 India
5. Department of Mathematics Indian Institute of Engineering Science and Technology Shibpur Howrah 711103 India
6. Department of Physics Zhejiang Normal University Jinhua 321004 Peoples Republic of China
7. New Uzbekistan University Mustaqillik ave. 54 100007 Tashkent Uzbekistan
Abstract
AbstractIn this study, the framework of Horava‐Lifshitz gravity to model the Universe's dark matter and dark energy (DE) components is adopted. Specifically, two recent parametrizations for DE models: the CBDRM‐type and CADMM‐type parameterizations is considered. In the analysis, the Hubble parameter is explicitly expressed, denoted as , for these two distinct dark energy models. By doing so, investigate and quantify the accelerated cosmic expansion rate characterizing the late‐time Universe is aimed. This study uses a wide range of datasets. This dataset consists of recent measurements of baryon acoustic oscillations (BAOs) collected over a period of 22 years with the Cosmic Chronometers (CC) dataset, Type Ia supernovae (SNIa) dataset, the Hubble diagram of gamma‐ray bursts (GRBs), quasars (Q), and the latest measurement of the Hubble constant (R22). Consequently, a crucial aspect of this study by plotting the vs. H0 plane is presented. In the context of the ΛCDM model, after incorporating all the datasets, including the R22 prior, the following results: H0 = 71.674089 ± 0.734089 and is obtained. For the CBDRM model, H0 = 72.355058 ± 1.004604 and is found. In the case of the CADMM model, the analysis yields H0 = 72.347804 ± 0.923328 and . Cosmographic analyses for both of the proposed parameterizations in comparison to the ΛCDM paradigm are conducted. Additionally, Diagnostic tests to investigate the evolution of both models is applied. Finally, the Information Criteria test demonstrates that the ΛCDM model emerges as the preferred choice among the models is considered.
Funder
Council of Scientific and Industrial Research, India
Subject
General Physics and Astronomy