Abstract: Efficient removal of radioactive cobalt ions is essential for ensuring the safety of nuclear power operations. Although natural or synthetic zeolites exhibit moderate removal performance for Co²⁺, they suffer from insufficient removal depth due to strongly relying on sole cation-exchange mechanism. To tackle this challenge, we successfully synthesized a series of nitrogen-functionalized NaA zeolites via an in situ strategy. Among them, the imidazoline-functionalized zeolite (IM-NaA) exhibits a distribution coefficient (K_d) of 3.95×10⁶ mL/g, which is an order of magnitude higher than that of pristine NaA, revealing enhanced affinity toward Co²⁺ ions. These zeolites also feature rapid adsorption kinetics and satisfied selectivity. X-Ray photoelectron spectroscopy (XPS) analysis confirms that the enhanced capture is achieved through the concurrent processes of Na⁺/Co²⁺ exchange and coordination between Co²⁺ and the functionalized nitrogen sites. This study provides an effective strategy for the rational design of zeolite-based adsorbents for the deep decontamination of cobalt ions.

Key words: Zeolite, Cobalt, Adsorption, In situ synthesis, Functional modification