Quantum entropy-driven modifications to holographic dark energy in f(G, T) gravity
Abstract In this work, we present a f(G, T) gravity-based reconstruction of Barrow Holographic Dark Energy (BHDE). This approach extends the conventional HDE model by replacing the standard Bekenstein–Hawking entropy with Barrow entropy, which encapsulates quantum gravitational corrections to the ge...
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SpringerOpen
2025-05-01
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| Series: | European Physical Journal C: Particles and Fields |
| Online Access: | https://doi.org/10.1140/epjc/s10052-025-14272-0 |
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| author | Giuseppe Gaetano Luciano |
| author_facet | Giuseppe Gaetano Luciano |
| author_sort | Giuseppe Gaetano Luciano |
| collection | DOAJ |
| description | Abstract In this work, we present a f(G, T) gravity-based reconstruction of Barrow Holographic Dark Energy (BHDE). This approach extends the conventional HDE model by replacing the standard Bekenstein–Hawking entropy with Barrow entropy, which encapsulates quantum gravitational corrections to the geometry of black hole horizons. We explore the cosmological dynamics of a spatially flat Friedmann–Robertson–Walker background filled with a pressureless dust fluid, considering both conserved and non-conserved energy–momentum tensor models. To this end, we employ the Hubble horizon as the infrared cutoff and adopt a power-law ansatz for the scale factor. We then investigate the evolution of key cosmological parameters, including the equation-of-state parameter $$ \omega _{GT} ,$$ ω GT , the deceleration parameter q, and the squared sound speed $$ v_s^2 .$$ v s 2 . Furthermore, we explore the dynamical behavior in the $$ \omega _{GT} $$ ω GT - $$ \omega '_{GT} $$ ω GT ′ phase space. In the case of conserved energy–momentum tensor, our findings indicate that the BHDE model evolves from a quintessence-like regime into the phantom domain. This transition supports the current accelerated expansion of the Universe and offers an improvement over the original HDE model, which does not adequately account for the observed phenomenology. The corresponding $$ \omega _{GT} $$ ω GT - $$ \omega '_{GT} $$ ω GT ′ trajectory lies within the freezing region of the phase space. On the other hand, within the non-conserved framework, the BHDE model exhibits phantom-like behavior in the early Universe, subsequently evolving toward either a cosmological constant-like state or a quintessence-like regime. Notably, unlike the conserved scenario, the squared sound speed $$ v_s^2 $$ v s 2 asymptotically attains positive values in the far future, signifying a stable configuration. Moreover, the trajectory in the $$ \omega _{GT} $$ ω GT - $$ \omega '_{GT} $$ ω GT ′ phase space displays a thawing behavior. Finally, we evaluate the observational viability of our results and compare them with predictions from alternative reconstructed dark energy models. |
| format | Article |
| id | doaj-art-6bdb10a5b7034e7ca38a87ff4b3727e1 |
| institution | OA Journals |
| issn | 1434-6052 |
| language | English |
| publishDate | 2025-05-01 |
| publisher | SpringerOpen |
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| series | European Physical Journal C: Particles and Fields |
| spelling | doaj-art-6bdb10a5b7034e7ca38a87ff4b3727e12025-08-20T02:03:38ZengSpringerOpenEuropean Physical Journal C: Particles and Fields1434-60522025-05-0185511810.1140/epjc/s10052-025-14272-0Quantum entropy-driven modifications to holographic dark energy in f(G, T) gravityGiuseppe Gaetano Luciano0Department of Chemistry, Physics and Environmental and Soil Sciences, Escola Politècnica Superior, Universidad de LleidaAbstract In this work, we present a f(G, T) gravity-based reconstruction of Barrow Holographic Dark Energy (BHDE). This approach extends the conventional HDE model by replacing the standard Bekenstein–Hawking entropy with Barrow entropy, which encapsulates quantum gravitational corrections to the geometry of black hole horizons. We explore the cosmological dynamics of a spatially flat Friedmann–Robertson–Walker background filled with a pressureless dust fluid, considering both conserved and non-conserved energy–momentum tensor models. To this end, we employ the Hubble horizon as the infrared cutoff and adopt a power-law ansatz for the scale factor. We then investigate the evolution of key cosmological parameters, including the equation-of-state parameter $$ \omega _{GT} ,$$ ω GT , the deceleration parameter q, and the squared sound speed $$ v_s^2 .$$ v s 2 . Furthermore, we explore the dynamical behavior in the $$ \omega _{GT} $$ ω GT - $$ \omega '_{GT} $$ ω GT ′ phase space. In the case of conserved energy–momentum tensor, our findings indicate that the BHDE model evolves from a quintessence-like regime into the phantom domain. This transition supports the current accelerated expansion of the Universe and offers an improvement over the original HDE model, which does not adequately account for the observed phenomenology. The corresponding $$ \omega _{GT} $$ ω GT - $$ \omega '_{GT} $$ ω GT ′ trajectory lies within the freezing region of the phase space. On the other hand, within the non-conserved framework, the BHDE model exhibits phantom-like behavior in the early Universe, subsequently evolving toward either a cosmological constant-like state or a quintessence-like regime. Notably, unlike the conserved scenario, the squared sound speed $$ v_s^2 $$ v s 2 asymptotically attains positive values in the far future, signifying a stable configuration. Moreover, the trajectory in the $$ \omega _{GT} $$ ω GT - $$ \omega '_{GT} $$ ω GT ′ phase space displays a thawing behavior. Finally, we evaluate the observational viability of our results and compare them with predictions from alternative reconstructed dark energy models.https://doi.org/10.1140/epjc/s10052-025-14272-0 |
| spellingShingle | Giuseppe Gaetano Luciano Quantum entropy-driven modifications to holographic dark energy in f(G, T) gravity European Physical Journal C: Particles and Fields |
| title | Quantum entropy-driven modifications to holographic dark energy in f(G, T) gravity |
| title_full | Quantum entropy-driven modifications to holographic dark energy in f(G, T) gravity |
| title_fullStr | Quantum entropy-driven modifications to holographic dark energy in f(G, T) gravity |
| title_full_unstemmed | Quantum entropy-driven modifications to holographic dark energy in f(G, T) gravity |
| title_short | Quantum entropy-driven modifications to holographic dark energy in f(G, T) gravity |
| title_sort | quantum entropy driven modifications to holographic dark energy in f g t gravity |
| url | https://doi.org/10.1140/epjc/s10052-025-14272-0 |
| work_keys_str_mv | AT giuseppegaetanoluciano quantumentropydrivenmodificationstoholographicdarkenergyinfgtgravity |