Spherically symmetric vacuum solutions in 1-Parameter New General Relativity and their phenomenology
Abstract: In this work, we study spherically symmetric vacuum solutions in 1-parameter New General Relativity (NGR), a specific theory in teleparallel gravity which is constructed from the three possible quadratic scalars obtained from torsion with arbitrary coefficients satisfying the requirements for the absence of ghosts. In this class of modified theories of gravity, the observable effects of gravity result from the torsion rather than the curvature of the spacetime. Unlike in GR, where the fundamental quantity is the metric from which the Levi-Civita connection is derived, in teleparallel theories of gravity the fundamental variable is the tetrad, from which one constructs the metric and the teleparallel connection. We consider the most general tetrad for spherical symmetry and we derive the corresponding field equations. Under adequate assumptions, we find three different branches of vacuum solutions and discuss their associated phenomenology. In particular, we analyze the photon sphere, the classical tests of GR such as the light deflection, the Shapiro delay, and the perihelion shift, and also the Komar mass, while providing a detailed comparison with their Schwarzschild spacetime counterparts. Finally, we analyze how the observational imprints from accretion disks and shadows are affected in comparison with their GR counterparts, and conclude that the free parameters of the model might induce additional attractive or repulsive effects to the propagation of photons, depending on their values.
- C. M. Will, “The Confrontation between General Relativity and Experiment,” Living Rev. Rel. 17 (2014) 4, arXiv:1403.7377 [gr-qc].
- C. M. Will, Theory and Experiment in Gravitational Physics. Cambridge University Press, 2018. https://www.cambridge.org/academic/subjects/physics/cosmology-relativity-and-gravitation/theory-and-experiment-gravitational-physics-2nd-edition?format=AR&isbn=9781108679824.
- T. Baker, D. Psaltis, and C. Skordis, “Linking Tests of Gravity On All Scales: from the Strong-Field Regime to Cosmology,” Astrophys. J. 802 (2015) 63, arXiv:1412.3455 [astro-ph.CO].
- A. Einstein, “The foundation of the general theory of relativity.,” Annalen Phys. 49 (1916) no. 7, 769–822.
- R. H. Dicke, “New Research on Old Gravitation,”Science 129 (Mar., 1959) 621–624.
- L. I. Schiff, “On Experimental Tests of the General Theory of Relativity,”American Journal of Physics 28 (Apr., 1960) 340–343.
- A. Milani, D. Vokrouhlický, D. Villani, C. Bonanno, and A. Rossi, “Testing general relativity with the bepicolombo radio science experiment,”Phys. Rev. D 66 (Oct, 2002) 082001. https://link.aps.org/doi/10.1103/PhysRevD.66.082001.
- E. Fomalont, S. Kopeikin, G. Lanyi, and J. Benson, “Progress in Measurements of the Gravitational Bending of Radio Waves Using the VLBA,”Astrophys. J. 699 (July, 2009) 1395–1402, arXiv:0904.3992 [astro-ph.CO].
- I. I. Shapiro, “Fourth Test of General Relativity,”Phys. Rev. Lett. 13 (Dec., 1964) 789–791.
- K. Nordtvedt, “Testing relativity with laser ranging to the moon,”Phys. Rev. 170 (Jun, 1968) 1186–1187. https://link.aps.org/doi/10.1103/PhysRev.170.1186.
- J. G. Williams, S. G. Turyshev, and D. H. Boggs, “Progress in lunar laser ranging tests of relativistic gravity,”Phys. Rev. Lett. 93 (Dec, 2004) 261101. https://link.aps.org/doi/10.1103/PhysRevLett.93.261101.
- E. J. Copeland, M. Sami, and S. Tsujikawa, “Dynamics of dark energy,” Int. J. Mod. Phys. D 15 (2006) 1753–1936, arXiv:hep-th/0603057.
- E. Di Valentino, O. Mena, S. Pan, L. Visinelli, W. Yang, A. Melchiorri, D. F. Mota, A. G. Riess, and J. Silk, “In the realm of the Hubble tension—a review of solutions,” Class. Quant. Grav. 38 (2021) no. 15, 153001, arXiv:2103.01183 [astro-ph.CO].
- N. Schöneberg, G. Franco Abellán, A. Pérez Sánchez, S. J. Witte, V. Poulin, and J. Lesgourgues, “The H0 Olympics: A fair ranking of proposed models,” Phys. Rept. 984 (2022) 1–55, arXiv:2107.10291 [astro-ph.CO].
- T. Clifton, P. G. Ferreira, A. Padilla, and C. Skordis, “Modified Gravity and Cosmology,” Phys. Rept. 513 (2012) 1–189, arXiv:1106.2476 [astro-ph.CO].
- S. Nojiri and S. D. Odintsov, “Unified cosmic history in modified gravity: from F(R) theory to Lorentz non-invariant models,” Phys. Rept. 505 (2011) 59–144, arXiv:1011.0544 [gr-qc].
- L. Heisenberg, “A systematic approach to generalisations of General Relativity and their cosmological implications,” Phys. Rept. 796 (2019) 1–113, arXiv:1807.01725 [gr-qc].
- Springer, 2021. arXiv:2105.12582 [gr-qc].
- S. Capozziello and M. De Laurentis, “Extended Theories of Gravity,” Phys. Rept. 509 (2011) 167–321, arXiv:1108.6266 [gr-qc].
- T. P. Sotiriou and V. Faraoni, “f(R) Theories Of Gravity,” Rev. Mod. Phys. 82 (2010) 451–497, arXiv:0805.1726 [gr-qc].
- F. W. Hehl, J. D. McCrea, E. W. Mielke, and Y. Ne’eman, “Metric affine gauge theory of gravity: Field equations, Noether identities, world spinors, and breaking of dilation invariance,” Phys. Rept. 258 (1995) 1–171, arXiv:gr-qc/9402012 [gr-qc].
- A. Jiménez Cano, Metric-affine Gauge theories of gravity. Foundations and new insights. PhD thesis, Granada U., Theor. Phys. Astrophys., 2021. arXiv:2201.12847 [gr-qc].
- J. Beltrán Jiménez, L. Heisenberg, and T. S. Koivisto, “The Geometrical Trinity of Gravity,” Universe 5 (2019) no. 7, 173, arXiv:1903.06830 [hep-th].
- J. Beltrán Jiménez, L. Heisenberg, D. Iosifidis, A. Jiménez-Cano, and T. S. Koivisto, “General teleparallel quadratic gravity,” Phys. Lett. B 805 (2020) 135422, arXiv:1909.09045 [gr-qc].
- Springer, Dordrecht, 2013.
- S. Bahamonde, K. F. Dialektopoulos, C. Escamilla-Rivera, G. Farrugia, V. Gakis, M. Hendry, M. Hohmann, J. Levi Said, J. Mifsud, and E. Di Valentino, “Teleparallel gravity: from theory to cosmology,” Rept. Prog. Phys. 86 (2023) no. 2, 026901, arXiv:2106.13793 [gr-qc].
- M. Krssak, R. van den Hoogen, J. Pereira, C. Böhmer, and A. Coley, “Teleparallel theories of gravity: illuminating a fully invariant approach,” Class. Quant. Grav. 36 (2019) no. 18, 183001, arXiv:1810.12932 [gr-qc].
- K. Hayashi and T. Shirafuji, “New General Relativity,” Phys. Rev. D 19 (1979) 3524–3553. [Addendum: Phys.Rev.D 24, 3312–3314 (1982)].
- K. Hayashi and T. Shirafuji, “Addendum to ”new general relativity”,” Phys. Rev. D 24 (1981) 3312–3314. https://link.aps.org/doi/10.1103/PhysRevD.24.3312.
- J. Beltrán Jiménez and K. F. Dialektopoulos, “Non-Linear Obstructions for Consistent New General Relativity,” JCAP 01 (2020) 018, arXiv:1907.10038 [gr-qc].
- P. Mitrić, “Canonical Structure of the Teleparallel Equivalent of General Relativity,” arXiv:1910.02810 [gr-qc].
- W.-H. Cheng, D.-C. Chern, and J. M. Nester, “Canonical Analysis of the One Parameter Teleparallel Theory,” Phys. Rev. D 38 (1988) 2656–2658.
- A. Okolow and J. Swiezewski, “Hamiltonian formulation of a simple theory of the teleparallel geometry,” Class. Quant. Grav. 29 (2012) 045008, arXiv:1111.5490 [math-ph].
- D. Blixt, M. Hohmann, and C. Pfeifer, “Hamiltonian and primary constraints of new general relativity,” Phys. Rev. D 99 (2019) no. 8, 084025, arXiv:1811.11137 [gr-qc].
- M. Hohmann, “Hamiltonian of new general relativity using differential forms,” Int. J. Mod. Phys. A 35 (2020) no. 02n03, 2040014, arXiv:1907.08343 [gr-qc].
- D. Blixt, M. Hohmann, and C. Pfeifer, “On the gauge fixing in the Hamiltonian analysis of general teleparallel theories,” Universe 5 (2019) no. 6, 143, arXiv:1905.01048 [gr-qc].
- D. Blixt, M. Hohmann, M. Krššák, and C. Pfeifer, “Hamiltonian analysis in new general relativity,” in 15th Marcel Grossmann Meeting on Recent Developments in Theoretical and Experimental General Relativity, Astrophysics, and Relativistic Field Theories. 5, 2019. arXiv:1905.11919 [gr-qc].
- M.-J. Guzman and S. Khaled Ibraheem, “Classification of primary constraints for new general relativity in the premetric approach,” Int. J. Geom. Meth. Mod. Phys. 18 (2021) no. supp01, 2140003, arXiv:2009.13430 [gr-qc].
- D. Blixt, M.-J. Guzmán, M. Hohmann, and C. Pfeifer, “Review of the Hamiltonian analysis in teleparallel gravity,” Int. J. Geom. Meth. Mod. Phys. 18 (2021) no. supp01, 2130005, arXiv:2012.09180 [gr-qc].
- U. Ualikhanova and M. Hohmann, “Parametrized post-Newtonian limit of general teleparallel gravity theories,” Phys. Rev. D 100 (2019) no. 10, 104011, arXiv:1907.08178 [gr-qc].
- M. Hohmann, “Polarization of gravitational waves in general teleparallel theories of gravity,” Astron. Rep. 62 (2018) no. 12, 890–897, arXiv:1806.10429 [gr-qc].
- M. Hohmann, M. Krššák, C. Pfeifer, and U. Ualikhanova, “Propagation of gravitational waves in teleparallel gravity theories,” Phys. Rev. D 98 (2018) no. 12, 124004, arXiv:1807.04580 [gr-qc].
- M. Mylova, J. Levi Said, and E. N. Saridakis, “General effective field theory of teleparallel gravity,” Class. Quant. Grav. 40 (2023) no. 12, 125002, arXiv:2211.11420 [gr-qc].
- S. Bahamonde, A. Golovnev, M.-J. Guzmán, J. L. Said, and C. Pfeifer, “Black holes in f(T,B) gravity: exact and perturbed solutions,” JCAP 01 (2022) no. 01, 037, arXiv:2110.04087 [gr-qc].
- S. Bahamonde, L. Ducobu, and C. Pfeifer, “Scalarized black holes in teleparallel gravity,” JCAP 04 (2022) no. 04, 018, arXiv:2201.11445 [gr-qc].
- S. Bahamonde, D. D. Doneva, L. Ducobu, C. Pfeifer, and S. S. Yazadjiev, “Spontaneous scalarization of black holes in Gauss-Bonnet teleparallel gravity,” Phys. Rev. D 107 (2023) no. 10, 104013, arXiv:2212.07653 [gr-qc].
- A. Golovnev, A. N. Semenova, and V. P. Vandeev, “Static spherically symmetric solutions in new general relativity,” Class. Quant. Grav. 41 (2024) no. 5, 055009, arXiv:2305.03420 [gr-qc].
- M. Hohmann, L. Järv, M. Krššák, and C. Pfeifer, “Modified teleparallel theories of gravity in symmetric spacetimes,” Phys. Rev. D 100 (2019) no. 8, 084002, arXiv:1901.05472 [gr-qc].
- M. Hohmann, “Metric-affine Geometries With Spherical Symmetry,” Symmetry 12 (2020) no. 3, 453, arXiv:1912.12906 [math-ph].
- J. a. L. Rosa, C. F. B. Macedo, and D. Rubiera-Garcia, “Imaging compact boson stars with hot spots and thin accretion disks,” Phys. Rev. D 108 (2023) no. 4, 044021, arXiv:2303.17296 [gr-qc].
- J. a. L. Rosa, “Observational properties of relativistic fluid spheres with thin accretion disks,” Phys. Rev. D 107 (2023) no. 8, 084048, arXiv:2302.11915 [gr-qc].
- G. J. Olmo, J. L. Rosa, D. Rubiera-Garcia, and D. Saez-Chillon Gomez, “Shadows and photon rings of regular black holes and geonic horizonless compact objects,” Class. Quant. Grav. 40 (2023) no. 17, 174002, arXiv:2302.12064 [gr-qc].
- J. a. L. Rosa and D. Rubiera-Garcia, “Shadows of boson and Proca stars with thin accretion disks,” Phys. Rev. D 106 (2022) no. 8, 084004, arXiv:2204.12949 [gr-qc].
- L. F. D. da Silva, F. S. N. Lobo, G. J. Olmo, and D. Rubiera-Garcia, “Photon rings as tests for alternative spherically symmetric geometries with thin accretion disks,” Phys. Rev. D 108 (2023) no. 8, 084055, arXiv:2307.06778 [gr-qc].
- M. Guerrero, G. J. Olmo, D. Rubiera-Garcia, and D. Sáez-Chillón Gómez, “Multiring images of thin accretion disk of a regular naked compact object,” Phys. Rev. D 106 (2022) no. 4, 044070, arXiv:2205.12147 [gr-qc].
- M. Guerrero, G. J. Olmo, D. Rubiera-Garcia, and D. Gómez Sáez-Chillón, “Light ring images of double photon spheres in black hole and wormhole spacetimes,” Phys. Rev. D 105 (2022) no. 8, 084057, arXiv:2202.03809 [gr-qc].
- G. J. Olmo, D. Rubiera-Garcia, and D. S.-C. Gómez, “New light rings from multiple critical curves as observational signatures of black hole mimickers,” Phys. Lett. B 829 (2022) 137045, arXiv:2110.10002 [gr-qc].
- M. Guerrero, G. J. Olmo, D. Rubiera-Garcia, and D. S.-C. Gómez, “Shadows and optical appearance of black bounces illuminated by a thin accretion disk,” JCAP 08 (2021) 036, arXiv:2105.15073 [gr-qc].
- 2014. arXiv:1302.6983 [gr-qc].
- P. van Nieuwenhuizen, “On ghost-free tensor lagrangians and linearized gravitation,” Nuclear Physics B 60 (1973) 478–492. https://www.sciencedirect.com/science/article/pii/0550321373901946.
- A. Ishihara, Y. Suzuki, T. Ono, T. Kitamura, and H. Asada, “Gravitational bending angle of light for finite distance and the Gauss-Bonnet theorem,” Phys. Rev. D 94 (2016) no. 8, 084015, arXiv:1604.08308 [gr-qc].
- S. M. Carroll, Spacetime and Geometry: An Introduction to General Relativity. Cambridge University Press, 7, 2019.
- S. E. Gralla, A. Lupsasca, and D. P. Marrone, “The shape of the black hole photon ring: A precise test of strong-field general relativity,” Phys. Rev. D 102 (2020) no. 12, 124004, arXiv:2008.03879 [gr-qc].
Paper Prompts
Sign up for free to create and run prompts on this paper using GPT-5.
Top Community Prompts
Collections
Sign up for free to add this paper to one or more collections.