DFT study of free radical scavenging mechanisms in UiO-66-(OH)(2) and UiO-66-NH(2) MOFs.

This study employs density functional theory (DFT) to investigate three common free radical scavenging mechanisms (hydrogen atom transfer (HAT), single electron transfer proton transfer (SET-PT), and sequential proton loss electron transfer (SPLET)) in UiO-66-(OH)(2) and UiO-66-NH(2) metal-organic framework (MOF) nanoparticles under gas, benzene and aqueous phase conditions. The reaction processes between UiO-66-(OH)(2)/UiO-66-NH(2) and hydroxyl radicals (˙OH) were simulated to elucidate detailed radical capture pathways, and the computational results were validated by macroscopic DPPH radical scavenging experiments. The results indicate that: (1) among the three mechanisms, HAT consistently exhibits the lowest bond dissociation energy across all phases, suggesting MOF nanoparticles preferentially undergo hydrogen atom transfer over electron transfer during radical scavenging; (2) compared to gas phase and nonpolar solvent (benzene), polar solvent (water) significantly lowers the energy barriers for both electron transfer and hydrogen transfer, thus enhancing reactivity across all mechanisms; (3) UiO-66-(OH)(2) exhibits a radical scavenging rate constant of 1.0 × 10(9) M(-1) s(-1), higher than 7.63 × 10(8) M(-1) s(-1) for UiO-66-NH(2); (4) DPPH assays reveal that UiO-66-(OH)(2) exhibits an 8% greater radical scavenging efficiency than UiO-66-NH(2), in agreement with DFT predictions and confirming the antioxidative benefit of hydroxyl functionalization. This study proposes a combined DFT and experimental screening workflow for radical scavengers, offering an efficient and economical approach to rapidly identify novel MOF-based radioprotective radical scavengers.