Reconstruction of the Quintessence Dark Energy Potential from a Gaussian Process

IF 0.6 4区物理与天体物理 Q4 ASTRONOMY & ASTROPHYSICS

Astrophysics Pub Date : 2024-07-31 DOI:10.1007/s10511-024-09828-z

E. Elizalde, M. Khurshudyan, K. Myrzakulov, S. Bekov

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Abstract

This paper presents the reconstruction of the quintessence dark energy potential in a model- independent way. Reconstruction relies on a Gaussian process and on available expansion rate data. Specifically, 40-point values of H(z) are used, consisting of a 30-point sample deduced from a differential age method and an additional 10-point sample obtained from the radial BAO method. Results are obtained for two kernel functions and for three different values of H₀. This sheds light on the H₀ tension problem indicating that it is not just a numerical problem. The model-independent reconstruction of the potential can serve as a reference to constraint available models and construct new ones. Various possibilities, including V(ϕ) ~ e^-λϕ , are compared with the reconstructions here obtained, which is notably the first truly model-independent reconstruction of the quintessence dark energy potential. This allows the selection of new models that can be interesting for cosmology. The method can be extended to reconstruct the potential of related dark energy models, to be considered in future work.

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从高斯过程重构五子暗能量势

本文以一种与模型无关的方式介绍了五重暗能量势的重建。重建依赖于高斯过程和现有的膨胀率数据。具体来说，本文使用了 40 点 H(z)值，其中包括从差分年龄法推导出的 30 点样本和从径向 BAO 法获得的额外 10 点样本。两种核函数和三种不同的 H0 值都得到了结果。这揭示了 H0 张力问题，表明它不仅仅是一个数值问题。与模型无关的势重构可以作为约束现有模型和构建新模型的参考。包括 V(ϕ) ~ e-λϕ 在内的各种可能性都与这里得到的重建进行了比较，这显然是第一个真正与模型无关的五元暗能量势重建。这样就可以选择对宇宙学有意义的新模型。该方法可以扩展到重建相关暗能量模型的势，这将在今后的工作中加以考虑。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Astrophysics 地学天文-天文与天体物理

CiteScore

0.90

自引率

20.00%

发文量

审稿时长

6-12 weeks

期刊介绍： Astrophysics (Ap) is a peer-reviewed scientific journal which publishes research in theoretical and observational astrophysics. Founded by V.A.Ambartsumian in 1965 Astrophysics is one of the international astronomy journals. The journal covers space astrophysics, stellar and galactic evolution, solar physics, stellar and planetary atmospheres, interstellar matter. Additional subjects include chemical composition and internal structure of stars, quasars and pulsars, developments in modern cosmology and radiative transfer.