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This study employs density functional theory (DFT) to investigate the reaction mechanisms of NH3 selective catalytic reduction of NO on Ni-doped CeVO₄ (200) surfaces, as well as the mechanism of sulfur poisoning, to understand the impact of Ni doping on the catalytic performance and sulfur resistance of CeVO₄ catalysts. We systematically examined the NH₃-SCR mechanism on NiCeVO₄, including two consecutive NO reduction pathways. Simulations of the adsorption/dissociation behavior of NH₃, O₂, and NO molecules on the catalyst, both before and after doping were conducted. The results indicate that Ni doping significantly alters the electronic charge properties of the CeVO₄ surface, markedly improving the adsorption characteristics of gas molecules and considerably lowering the dissociation energy barrier. In both CeVO₄ and Ni-CeVO₄ catalyst systems, the reaction follows the Eley-Rideal mechanism. The Ni doping reduces the activation barriers for the formation of intermediates NH₂ and NH₂NO, with NH₂ formation identified as the rate-determining step. Additionally, the adsorption of SO₂ and H₂O and the dissociation pathways of ammonium sulfate before and after doping were studied. It was found that Ni doping considerably reduces the adsorption of H₂O and SO₂ and lowers the dissociation barrier of ammonium sulfate, thereby enhancing the catalyst’s water and sulfur resistance.