Temperature evolution of the FRW Universe in the viscous generalised Chaplygin gas model

IF 2.1 4区物理与天体物理 Q2 PHYSICS, MULTIDISCIPLINARY

Pramana Pub Date : 2025-07-14 DOI:10.1007/s12043-025-02959-8

Abhinath Barman

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引用次数: 0

Abstract

In this paper, we study the temperature evolution of the Friedmann–Robertson–Walker (FRW) Universe filled with viscous generalised Chaplygin gas (VGCG) as a model of dark energy. We started the thermodynamical treatment of the VGCG, which is given by the equation of state \(p=-\frac{A}{\rho ^{\alpha }}\) with bulk viscosity in the framework of the Eckart theory. We investigated it in the cosmological model using the FRW metric in flat space–time, and we were able to determine its temperature as a function of redshift z. Besides, the expression for the fluid’s temperature in terms of redshift and the viscosity parameter \(\xi _{0}\) is derived. In our computation, we assumed that the value of the parameter \(\Omega _{x}\) would be 0.7 and that the current value of the temperature of the microwave background radiation would be given by \(T_{0}=2.7\) K. Using the decoupling redshift value \((z\approx 1100)\) and the viscous parameter, the decoupling temperature is computed. The optimum choices for the remaining parameters are \(\alpha =0.25\), \(\Omega _{x}=0.75\), \(\xi _{0}=-0.1930\), yielding a decoupling temperature of \(T(z=1100)\approx 4000\) K and a redshift of \(z\approx 0.25\). We also compute the decoupling temperature in this model at \(\ddot{a}=0\) and \(T_{0}=2.7\) K. In terms of z and \(\xi _{0}\), we also examined other parameters, such as the Hubble parameter, the equation of state parameter, the adiabatic speed of sound, jerk, snap and Om diagnostic parameters. These values are then compared with the outcomes of earlier research on modified Chaplygin gas (MCG) and other Chaplygin gas. We have shown that this model is thermodynamically stable for \(\xi _0 < 0\) in the FRW Universe and studied the validity of the generalised second law of thermodynamics on the apparent and event horizons of the Universe in the FRW Universe dominated by various Chaplygin gas fluids. However, a perfect fluid with \(\omega _{\textrm{eff}}<-\frac{1}{3}\) would produce an acceleration phase but might not produce a feasible dark energy epoch in the early and late stages of the Universe that is consistent with the observational data.

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粘性广义Chaplygin气体模型下FRW宇宙的温度演化

本文研究了充满粘性广义Chaplygin气体（VGCG）的FRW宇宙的温度演化。在Eckart理论的框架下，我们开始了VGCG的热力学处理，VGCG由具有体粘度的状态方程\(p=-\frac{A}{\rho ^{\alpha }}\)给出。我们利用平坦时空中的FRW度规在宇宙学模型中对其进行了研究，我们能够确定其温度是红移z的函数。此外，我们还推导了流体温度与红移和粘度参数\(\xi _{0}\)的表达式。在我们的计算中，我们假设参数\(\Omega _{x}\)的值为0.7，微波背景辐射温度的当前值为\(T_{0}=2.7\) k，利用解耦红移值\((z\approx 1100)\)和粘性参数，计算解耦温度。其余参数的最佳选择为\(\alpha =0.25\), \(\Omega _{x}=0.75\), \(\xi _{0}=-0.1930\)，得到的解耦温度为\(T(z=1100)\approx 4000\) K，红移为\(z\approx 0.25\)。我们还计算了该模型在\(\ddot{a}=0\)和\(T_{0}=2.7\) k处的解耦温度。对于z和\(\xi _{0}\)，我们还检查了其他参数，如哈勃参数，状态方程参数，绝热声速，jerk， snap和Om诊断参数。然后将这些值与先前对改性Chaplygin气体（MCG）和其他Chaplygin气体的研究结果进行比较。我们证明了该模型对于\(\xi _0 < 0\)在FRW宇宙中是热力学稳定的，并在由各种Chaplygin气体流体主导的FRW宇宙中研究了广义热力学第二定律在宇宙视界和事件界上的有效性。然而，具有\(\omega _{\textrm{eff}}<-\frac{1}{3}\)的完美流体将产生一个加速阶段，但可能不会在宇宙的早期和晚期产生与观测数据一致的可行的暗能量时代。

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

Pramana 物理-物理：综合

CiteScore

3.60

自引率

7.10%

发文量

206

审稿时长

3 months

期刊介绍： Pramana - Journal of Physics is a monthly research journal in English published by the Indian Academy of Sciences in collaboration with Indian National Science Academy and Indian Physics Association. The journal publishes refereed papers covering current research in Physics, both original contributions - research papers, brief reports or rapid communications - and invited reviews. Pramana also publishes special issues devoted to advances in specific areas of Physics and proceedings of select high quality conferences.