Non-metallic iodine single-atom catalysts with optimized electronic structures for efficient Fenton-like reactions.

In this study, we introduce a highly effective non-metallic iodine single-atom catalyst (SAC), referred to as I-NC, which is strategically confined within a nitrogen-doped carbon (NC) scaffold. This configuration features a distinctive C-I coordination that optimizes the electronic structure of the nitrogen-adjacent carbon sites. As a result, this arrangement enhances electron transfer from peroxymonosulfate (PMS) to the active sites, particularly the electron-deficient carbon. This electron transfer is followed by a deprotonation process that generates the peroxymonosulfate radical (SO₅^•−). Subsequently, the SO₅^•− radical undergoes a disproportionation reaction, leading to the production of singlet oxygen (¹O₂). Furthermore, the energy barrier for the rate-limiting step of SO₅^•− generation in I-NC is significantly lower at 1.45 eV, compared to 1.65 eV in the NC scaffold. This reduction in energy barrier effectively overcomes kinetic obstacles, thereby facilitating an enhanced generation of ¹O₂. Consequently, the I-NC catalyst exhibits remarkable catalytic efficiency and unmatched reactivity for PMS activation. This leads to a significantly accelerated degradation of pollutants, evidenced by a relatively high observed kinetic rate constant (k_obs ~ 0.436 min⁻¹) compared to other metallic SACs. This study offers valuable insights into the rational design of effective non-metallic SACs, showcasing their promising potential for Fenton-like reactions in water treatment applications. Electronic structure modulation of active sites is important for Fenton-like catalysis. A non-metallic iodine single-atom catalyst with C-I coordination is reported here, which can effectively activate peroxymonosulfate into ¹O₂ for water treatment. [ABSTRACT FROM AUTHOR]