Abstract
The mechanism of coating effects between ether molecules and iron (Fe) nanoparticles was generally estimated using first-principle calculations and molecular dynamic (MD) simulations coupling with Fe (110) crystal layers and sphere models. In the present work, the optimized adsorption site and its energy were confirmed. The single sphere model in MD simulations was studied for typical adsorption behaviors, and the double sphere model was built to be more focused on the gap impact between two particles. In those obtained results, it is demonstrated that ether molecules were prone to be adsorbed on the long bridge site of the Fe (110) crystal while comparing with other potential sites. Although the coating was not completely uniform at early stages, the formation of ether layer ended up being equilibrated finally. Accompanied with charge transfer, those coated ether molecules exerted much binding force on the shell Fe atoms. Additionally, when free ether molecules were close to the gap between two nanoparticles, they were found to come under double adsorption effects. Although this effect might not be sufficient to keep them adsorbed, the movement of these ether molecules were hindered to some extent.
Highlights
Nanomaterials refer to those material which have at least one dimension of structure in nanoscale.They are believed as one the most potential research field all over the world [1]
It is believed that the formation of ether coating layer will effectively isolate Fe surface from atmosphere, and not affect industrial performances of Fe nanoparticles
As one of the expected innovations in this study, a novel double-sphere model was induced to prove whether coating behaviors was affected by the gap between two Fe nanoparticles or not
Summary
Nanomaterials refer to those material which have at least one dimension of structure in nanoscale. Galdames et al generally applied Fe nanoparticles with those two kinds of coatings, respectively, for the application of lindane degradation It seems that previous coating studies for Fe nanoparticles mainly depended on experimental methods. The limitation of conventional DFT method is that issues like long-rang interactions were missed in its results In this case, some studies aimed to make corrections by considering long-range effects [25,26,27]. Some studies aimed to make corrections by considering long-range effects [25,26,27] We performed both MD simulations and DFT calculations to investigate the formation of ether coating layer on Fe nanoparticle surface. It is believed that the formation of ether coating layer will effectively isolate Fe surface from atmosphere, and not affect industrial performances of Fe nanoparticles. The passivation effect of ether layer will effectively enlarge the retention period of Fe nanoparticles, because the corrosion effect for Fe nanoparticles is hindered
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