Search

Your search keyword '"Pandey, Bramha Dutta"' showing total 10 results
Start Over Author "Pandey, Bramha Dutta" Publication Year Range Last 3 years
10 results on '"Pandey, Bramha Dutta"'

1. Holographic dark energy through Kaniadakis entropy in non flat universe

Author

P, Suresh Kumar, Pandey, Bramha Dutta, Sharma, Umesh Kumar, and Pankaj

Subjects
Physics - General Physics
Abstract

By extending the standard holographic principle to a cosmological framework and combining the non-flat condition with the Kaniadakis entropy, we construct the non-flat Kaniadakis holographic dark energy model. The model employs Kaniadakis parameter $K$ and a parameter $c$. Derivation of the differential equation for KHDE density parameter to describe the evolutionary behavior of the universe is obtained. Such a differential equation could explain both the open as well as closed universe models. The classification based on matter and dark energy (DE) dominated regimes show that the KHDE scenario may be used to specify the Universe's thermal history and that a quintom regime can be encountered. For open and closed both the cases, we find the expressions for the deceleration parameter and the equation of state (EoS) parameter. Also, by varying the associated parameters, classical stability of the method is established. On considering the curvature to be positive, the universe favors the quintom behavior for substantially smaller values as opposed to the flat condition, when only quintessence is attained for such $K$ values. Additionally, we see a similar behavior while considering the curvature to be negative for such $K$ values. Therefore, adding a little bit of spatial geometry that isn't flat to the KHDE enhances the phenomenology while maintaining $K$ values at lower levels. To validate the model parameters, the most recent $30\;H(z)$ dataset measurements, in the redshift range $0.07 \leq z \leq 1.965$ are utilized. In addition, the distance modulus measurement from the current Union 2.1 data set of type Ia supernovae are employed., Comment: 17 pages, 12 figures

Published
2022
Full Text
View/download PDF

2. New Tsallis Agegraphic Dark Energy

Author

Pankaj, Pandey, Bramha Dutta, Kumar, P. Suresh, and Sharma, Umesh Kumar

Subjects
General Relativity and Quantum Cosmology
Abstract

The proposed model is a study of the nature of dark energy through non-extensive Tsallis entropy. The method is based on the Karolyhazy relation which is a combined idea from quantum physics and general relativity. Dark energy is the energy density of quantum fluctuations in space-time. This is the key idea behind proposing agegraphic dark energy (ADE) models here. The parameter $\delta$ is used to measure the quantitative distinction from the standard scenario. To look at the cosmological implications of the hypothesized dark energy model, as well as the expansion of the Universe filled with zero pressure matter and the resulting dark energy alternatives, the role of IR cutoff is played by age of the universe. The dynamic behavior of dark energy density parameter is carried out. The expressions for the equation of state parameter and deceleration parameter are obtained. The analysis is performed by taking into account a no flow as well as a flow of energy among the dark matter and dark energy sectors of the universe., Comment: 10 pages, 20 figures

Published
2022
Full Text
View/download PDF

3. Kaniadakis Agegraphic Dark Energy

Author

P, Suresh Kumar, Pandey, Bramha Dutta, Pankaj, and Sharma, Umesh Kumar

Subjects
Physics - General Physics
Abstract

In this manuscript, we present a novel dark energy model to study the nature of dark energy. Non-extensive Kaniadakis entropy and, timescale as infrared cutoff are the major tools of the current study. Age of the Universe will serve the purpose of infrared cutoff. The cosmological characteristics of the proposed dark energy model, as well as the evolution of the cosmos filled with pressure-free matter and the ensuing dark energy candidates, are investigated. The interaction as well as non-interaction among the two sectors will also be considered. The differential equation for the dark energy density parameter, including the expression of the equation of state and deceleration parameters, are derived. The analysis of deceleration parameter clearly shows the universe to transit from decelerated to accelerated phase around $z\approx 0.6$. The squared sound speed is also plotted against redshift $z$ to check the stability behavior of the model for both the cases., Comment: 17 pages, 20 figures

Published
2022

4. New Tsallis Holographic Dark Energy

Author

Pandey, Bramha Dutta, P, Suresh Kumar, Pankaj, and Sharma, Umesh Kumar

Subjects
Physics - General Physics
Abstract

Tsallis entropy is a generalization of the Boltzmann-Gibbs entropy in statistical theory which uses a parameter $\delta$ to measure the deviation from the standard scenario quantitatively. Using concepts of Tsallis entropy and future event horizon, we construct a new Tsallis holographic dark energy model. The parameters $c$ and $\delta$ will be used to characterize various aspects of the model. Analytical expressions for various cosmological parameters such as the differential equation describing the evolution of the effective dark energy density parameter, the equation of state parameter and the deceleration parameter are obtained. The equation of state parameter for the current model exhibits the pure quintessence behaviour for $c>1$, quintom behaviour for $c<1$ whereas the $\Lambda$CDM model is recovered for $c=1$. To analyze the thermal history of the universe, we obtained the expression for the deceleration parameter and found that for $z \approx 0.6$, the phase transits from deceleration to acceleration., Comment: 14 pages, 7 figures

Published
2021
Full Text
View/download PDF

8. Quintessence reconstruction through new Tsallis holographic dark energy model.

Author

Sharma, Umesh Kumar, Pandey, Bramha Dutta, Suresh Kumar, P., and Pankaj

Subjects
*DARK energy, *SCALAR field theory, *EVOLUTION equations, *QUANTUM gravity, *DIFFERENTIAL equations, *EQUATIONS of state
Abstract

In statistical theory, the Tsallis entropy is an extended form of the Boltzmann–Gibbs entropy. The dimensionless parameter δ is employed to state the quantitative difference from the standard scenario. The concepts of Tsallis entropy and the future event horizon are employed in formulating the present new Tsallis holographic dark energy (NTHDE) model. The model attempts to explain the properties of dark energy using the foundation of quantum gravity. The differential equation characterizing the evolution of the NTHDE density parameter is obtained. Expressions stating the dynamic behavior such as equation of state (EoS), deceleration and jerk parameters are obtained in terms of the NTHDE density parameter. For δ < 1 , the quintessence nature of scalar field could completely characterize the NTHDE. A reconstruction of the scalar field's dynamics and quintessence potential is attempted. We demonstrate that the diagnosis made by statefinder is adaptive enough to distinguish between quintessence and cosmological constant-based dark energy models. Additionally, observational data obtained from CC + SNIa + 5 8 0 union 2.1 sources are used to evaluate the model's effectiveness. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

10. Phantom model for Tsallis holographic dark energy.

Author

Pandey, Bramha Dutta, Pankaj, and Sharma, Umesh Kumar

Subjects
*DARK energy, *SCALAR field theory, *EQUATIONS of state, *DENSITY of states, *ENERGY density, *VALUES (Ethics), *REDSHIFT
Abstract

This paper considers Tsallis holographic dark energy in an FLRW universe that is flat, with the future event horizon serving as an IR cutoff. We examine the evolutionary behavior of parameters related to dark energy density and the equation of state for different values of Tsallis exponent δ , and observe suitable behavior in the model. Here δ > 1 in lower redshift region corresponds to phantom behavior of Tsallis holographic dark energy. An effort is made to reconstruct the potential of the phantom for δ > 1 with lower redshift by examining the dynamics of the scalar field. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results