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Auteurs principaux: Anand, Ankit, Singh, Aditya, Mishra, Anshul, Gashti, Saeed Noori, Tangphati, Takol, Channuie, Phongpichit
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2507.00455
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author Anand, Ankit
Singh, Aditya
Mishra, Anshul
Gashti, Saeed Noori
Tangphati, Takol
Channuie, Phongpichit
author_facet Anand, Ankit
Singh, Aditya
Mishra, Anshul
Gashti, Saeed Noori
Tangphati, Takol
Channuie, Phongpichit
contents We investigate the thermodynamics, topology, and geometry of black holes in Lorentz-violating gravity. Modifications in the theory by perturbative parameter lead to coupled changes in horizon structure and thermodynamic behaviour, allowing us to derive generalized universal relations and explore implications for the Weak Gravity Conjecture. The thermodynamic topology reveals distinct topological charges, with photon spheres identified as robust topological defects. Our analysis shows that the Ruppeiner curvature remains universally negative across thermodynamic ensembles, indicating dominant attractive interactions among microstructures. This ensemble-independent behaviour highlights a fundamental thermodynamic universality in Lorentz-violating settings. Together, these results provide a consistent and rich framework for understanding black hole microphysics and gravitational consistency in modified theories. We further study the motion of timelike test particles in these black hole spacetimes by analyzing the effective potential shaped by the Lorentz-violating couplings. The resulting dynamics reveal the existence of bound orbits and stable circular trajectories, with the location of the innermost stable circular orbit and turning points significantly influenced by the parameters $\ell_{1,2}$, and the cosmological constant. Numerical simulations of trajectories in the $x-y,\,x-z$, and 3D planes show precessing, bounded, and plunging orbits, depending on the particle's specific energy and angular momentum. These results highlight how Lorentz-violating effects alter the structure of geodesic motion and provide potential observational signatures in the dynamics of massive particles near black holes.
format Preprint
id arxiv_https___arxiv_org_abs_2507_00455
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Black Holes in Lorentz-Violating Gravity: Thermodynamics, Geometry, and Particle Dynamics
Anand, Ankit
Singh, Aditya
Mishra, Anshul
Gashti, Saeed Noori
Tangphati, Takol
Channuie, Phongpichit
General Relativity and Quantum Cosmology
We investigate the thermodynamics, topology, and geometry of black holes in Lorentz-violating gravity. Modifications in the theory by perturbative parameter lead to coupled changes in horizon structure and thermodynamic behaviour, allowing us to derive generalized universal relations and explore implications for the Weak Gravity Conjecture. The thermodynamic topology reveals distinct topological charges, with photon spheres identified as robust topological defects. Our analysis shows that the Ruppeiner curvature remains universally negative across thermodynamic ensembles, indicating dominant attractive interactions among microstructures. This ensemble-independent behaviour highlights a fundamental thermodynamic universality in Lorentz-violating settings. Together, these results provide a consistent and rich framework for understanding black hole microphysics and gravitational consistency in modified theories. We further study the motion of timelike test particles in these black hole spacetimes by analyzing the effective potential shaped by the Lorentz-violating couplings. The resulting dynamics reveal the existence of bound orbits and stable circular trajectories, with the location of the innermost stable circular orbit and turning points significantly influenced by the parameters $\ell_{1,2}$, and the cosmological constant. Numerical simulations of trajectories in the $x-y,\,x-z$, and 3D planes show precessing, bounded, and plunging orbits, depending on the particle's specific energy and angular momentum. These results highlight how Lorentz-violating effects alter the structure of geodesic motion and provide potential observational signatures in the dynamics of massive particles near black holes.
title Black Holes in Lorentz-Violating Gravity: Thermodynamics, Geometry, and Particle Dynamics
topic General Relativity and Quantum Cosmology
url https://arxiv.org/abs/2507.00455