DESI DR2 BAO数据对Barrow和Tsallis全息暗能量的约束

IF 10.5 4区物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS

Journal of High Energy Astrophysics Pub Date : 2025-07-22 DOI:10.1016/j.jheap.2025.100427

Giuseppe Gaetano Luciano , Andronikos Paliathanasis , Emmanuel N. Saridakis

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引用次数: 0

摘要

Barrow和Tsallis全息暗能量（HDE）是最近提出的标准HDE框架的两个扩展，通过使用Barrow和Tsallis熵来结合对视界熵的广义修正。Tsallis熵来自非广泛的统计现象，它解释了长程相关性和可加性的偏差，而Barrow熵来自视界几何上的量子引力效应，与分形修改和变形有关。在宇宙学层面上，这两种情况导致相同的方程，尽管涉及的参数服从不同的理论界限。在这项工作中，我们使用Ia型超新星（SNIa）、宇宙天文钟（CC）和重子声学振荡（BAO）的观测数据，包括最近发布的DESI DR2数据集，对这两种情况进行了限制。我们证明两者都可以与观测一致，尽管它们不能减轻H0张力。然而，应用信息标准，我们推断两者都不受ΛCDM和谐宇宙学范式的青睐。

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Constraints on Barrow and Tsallis holographic dark energy from DESI DR2 BAO data

Barrow and Tsallis Holographic Dark Energy (HDE) are two recently proposed extensions of the standard HDE framework, incorporating generalized corrections to horizon entropy through the use of Barrow and Tsallis entropies. Tsallis entropy arises from non-extensive statistical phenomena which account for long-range correlations and deviations from additivity, while Barrow entropy emerges from quantum-gravitational effects on the horizon geometry, associated with fractal modifications and deformations. At the cosmological level, both scenarios lead to the same equations, nevertheless the involved parameters obey different theoretical bounds. In this work, we use observational data from Supernova Type Ia (SNIa), Cosmic Chronometers (CC) and Baryonic acoustic oscillations (BAO), including the recently released DESI DR2 dataset, to place constraints on both scenaria. We show that both can be in agreement with observations, although they cannot alleviate the

H_{0}

tension. However, applying information criteria we deduce that both of them are not favoured comparing to ΛCDM concordance cosmological paradigm.

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来源期刊

Journal of High Energy Astrophysics Earth and Planetary Sciences-Space and Planetary Science

CiteScore

9.70

自引率

5.30%

发文量

审稿时长

65 days

期刊介绍： The journal welcomes manuscripts on theoretical models, simulations, and observations of highly energetic astrophysical objects both in our Galaxy and beyond. Among those, black holes at all scales, neutron stars, pulsars and their nebula, binaries, novae and supernovae, their remnants, active galaxies, and clusters are just a few examples. The journal will consider research across the whole electromagnetic spectrum, as well as research using various messengers, such as gravitational waves or neutrinos. Effects of high-energy phenomena on cosmology and star-formation, results from dedicated surveys expanding the knowledge of extreme environments, and astrophysical implications of dark matter are also welcomed topics.