Constraints on Kalb-Ramond Gravity from EHT Observations of Rotating Black Holes in Traceless Conformal Electrodynamics

Abstract

We present a phenomenological study of rotating, charged black holes in Einstein gravity coupled to a traceless (conformal) matter sector formed by ModMax nonlinear electrodynamics and a Kalb-Ramond two-form that spontaneously breaks local Lorentz symmetry. Starting from a family of obtained static, Schwarzschild-like solutions with a traceless Kalb-Ramond sector, we construct the stationary, axisymmetric counterpart via the Newman-Janis algorithm. The resulting Newman-Kerr-like metric depends on four intrinsic parameters: the electric charge Q, the ModMax nonlinearity γ, the Lorentz-violation amplitude and the spin a. We analyze horizon structure and separatrices in parameter space, derive the null geodesic equations and obtain the photon capture boundary that defines the black hole shadow. Using ray-tracing, we compute shadow silhouettes and a suite of shadow observables (areal radius, characteristic radius Rs, distortion δ, oblateness D) and show how γ and produce qualitatively distinct effects: γ acts as a screening factor for the electromagnetic imprint, while introduces angular-dependent metric rescalings that deform shadow shape beyond simple size rescaling. We confront model predictions with EHT angular-radius measurements for M87* and Sgr A* and derive conservative bounds on the combinations of (Q,γ,,a). Our results identify an effective charge combination Q eff e-γQ2/(1-)2 and demonstrate that modest Q eff remains compatible with current EHT images while large Q eff is progressively disfavored.