Constraining Black Hole Shadows in Dunkl Spacetime using CUDA Numerical Computations
Abstract
With the help of CUDA high-performance numerical codes exploited in machine learning, we investigate the shadow aspect of new rotating and charged black holes using the Dunkl derivative formalism. Precisely, we first establish the corresponding metric function encoding the involved physical properties including the optical character. Exploiting such accelerated simulations, we approach the horizon radius behaviors in order to determine the regions of the module space providing physical solutions. Applying the Hamilton-Jacobi mechanism, we assess the shadow aspect for non-rotating and rotating solutions. Using such an aspect, we evaluate the energy rate of emission. Developing a high-performance CUDA numerical code, we derive strict constraints on the Dunkl deformation parameters in order to establish a link with the shadow observations provided by the Event Horizon Telescope collaboration.
Cite
@article{arxiv.2510.16460,
title = {Constraining Black Hole Shadows in Dunkl Spacetime using CUDA Numerical Computations},
author = {Saad Eddine Baddis and Adil Belhaj and Hajar Belmahi and Maryem Jemri},
journal= {arXiv preprint arXiv:2510.16460},
year = {2025}
}
Comments
22 pages, 8 figures, 2 tables, Latex, Authors are listed in alphabetical order