Understanding anti-corrosion mechanisms of the 2,6-dithiopurine (DTP) inhibitor molecule on iron surfaces

Abstract

Purine derivatives present a high efficiency for anti-corrosion purposes while the nanoscale mechanisms are not yet fully understood. In this work, the inhibition mechanism of the 2,6-dithiopurine (DTP) molecule was investigated using advanced characterizations and atomic simulations. We revealed that the DTP molecule undergoes a multi-layer adsorption mode and is governed by both chemisorption and physisorption processes. An organometallic layer at a thickness of ∼3.8 nm was captured using TEM, comprised of Fe-N and Fe-S bonds strongly anchored to the iron interfaces, as confirmed by the XPS analysis. Our quantum chemical calculations showed that heteroatoms such as N or S in the DTP molecule offer reactive sites that facilitate its chemisorption onto iron surfaces, to form metal-organic bonds (specifically, Fe-N and Fe-S) at the DTP-iron interfaces. We further employed molecular dynamics simulations to investigate the interaction between DTP molecule and various substrates. Our findings suggest that the hydroxyl groups on the lepidocrocite surface can significantly promote bonding between DTP and iron surfaces. Based on large-scale molecular dynamics simulations, we discovered that DTP can exhibit a strong binding affinity for aggressive ions, leading to a considerable decrease in the self-diffusion coefficient of hydronium ions of up to 70 %. This work provides a new understanding of anti-corrosion mechanisms and offers opportunities to design new corrosion inhibitors possessing multiple reactive sites and strong bonding with the substrate.