Probing Kalb-Ramond gravity with charged rotating black holes: constraints from EHT observations

Abstract

The Event Horizon Telescope (EHT) has guided strong-field gravitational physics by providing the first direct images of the supermassive black holes M87* and Sagittarius A*. The EHT observations offer unprecedented opportunities to test modified gravity theories against general relativity (GR). Motivated by this, we investigate charged rotating black holes in KR gravity, a framework motivated by string theory that incorporates spontaneous Lorentz symmetry breaking. The spacetime geometry is characterized by a Lorentz--violating parameter and electric charge Q, which modify the Kerr--Newman metric through a radial-dependent mass function. We compute black hole shadows and derive constraints on and Q using EHT observations of M87* and Sgr A*. For angular shadow diameter θ sh of M87* at inclination θo=17 and fixed Q=0.2, the EHT-allowed range θ sh∈(35.1,\,40.5)\,μas constrains the Lorentz--violating parameter to approximately -0.0190.075 and -0.0760.029 across the admissible spin interval. For angular shadow diameter θ sh of Sgr A* at inclination θo=50 and fixed Q=0.2, the corresponding EHT-allowed range θ sh∈(41.7,\,55.7)\,μas permits approximately -0.0750.110 and -0.1240.076 across the admissible spin interval. Our analysis reveals that the Lorentz-violating parameter suppresses the shadow radius by a factor 1-, while charge introduces additional distortions. Using the angular shadow diameter measured by EHT, we obtain an upper bound 0.19 from Sgr A* data with the stellar dynamics mass prior.