Swampland Criteria and Neutrino Generation in a Non-Cold Dark Matter Universe

IF 0.6 4区物理与天体物理 Q4 ASTRONOMY & ASTROPHYSICS Astrophysics Pub Date : 2023-09-29 DOI:10.1007/s10511-023-09800-3

M. Khurshudyan

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Abstract

In this paper, the implications of string Swampland criteria for a dark energy-dominated universe, where we have a deviation from the cold dark matter model, will be discussed. In particular, we have considered two models. One of them is one parameter model, while the second one has been crafted to reveal the dynamics in the deviation. The analysis has been obtained through the use of Gaussian processes (GPs) and H(z) expansion rate data (a 30-point sample deduced from a differential age method and a 10- point sample obtained from the radial BAO method). We learned that the tension with the Swampland criteria still will survive as in the cases of the models where dark matter is cold. In the analysis besides mentioned 40-point H(z) data, we used the latest values of H₀ reported by the Planck and Hubble missions to reveal possible solutions for the H₀ tension problem. Finally, the constraints on the neutrino generation number have been obtained revealing interesting results to be discussed yet. This and various related questions have been left to be discussed in forthcoming papers.

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Swampland准则与非冷暗物质宇宙中中微子的产生

在这篇论文中，我们将讨论弦Swampland准则对暗能量主导的宇宙的影响，在这个宇宙中，我们偏离了冷暗物质模型。我们特别考虑了两种模式。其中一个是单参数模型，而第二个模型是为了揭示偏差中的动态。分析是通过使用高斯过程（GP）和H（z）膨胀率数据（从微分年龄法推导的30点样本和从径向BAO法获得的10点样本）获得的。我们了解到，与Swampland标准的紧张关系仍然会像暗物质是冷的模型一样存在。在分析中，除了提到的40点H（z）数据外，我们还使用了普朗克和哈勃任务报告的H0的最新值，以揭示H0张力问题的可能解决方案。最后，获得了中微子生成数的约束条件，揭示了有趣的结果有待讨论。这一问题和各种相关问题有待于在今后的文件中讨论。

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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.