Mechanistic and kinetic insights into size-dependent activity in ultra-small Pt/CNTs nanozymes during antibacterial process

In enzyme-like catalytic reactions, the size effect of nanoparticles has been an essential yet unclear factor for the catalytic activity of nanozymes. Moreover, the synthesis of nanozymes with controllable size and electronic structures represents a grand challenge, which limits the systemic exploration the underlying nature of their structure–property relations and practical application. In this work, we proposed a novel strategy to regulate the size of Pt (0.55 ∼ 2.81 nm) by atomic layer deposition for precisely tailoring Pt-based nanozymes. The size-dependent electronic and kinetic effects have been observed for the peroxidase-like reaction and antibacterial process, revealing a volcano-type dependence of intrinsic activity on Pt nanoparticle sizes, and the optimum Pt nanoparticle size was found to be ca. 1.69 nm. A combination of kinetic study and XPS analyses, as well as multiple nanozyme characterizations, demonstrates that Pt nanoparticles with an appropriate size contribute to proper affinity to the substrates, relating to a high ratio of Pt0/Pt2+ on the surface of Pt nanoparticles, which is beneficial to obtain the excellent catalytic performance and antibacterial activity. Our work provides insights for an in-depth understanding size-dependent catalytic mechanism of nanozymes during antibacterial processes.