Adhesion of Bis-Salphen-Based Coordination Polymers to Graphene: Insights from Free Energy Perturbation Study

Author:

Pyrlin SergeyORCID,Lenzi VenieroORCID,Silva Alexandre,Ramos Marta,Marques LuísORCID

Abstract

Manipulation of nanoscale objects using molecular self-assembly is a potent tool to achieve large scale nanopatterning with small effort. Coordination polymers of bis-salphen compounds based on zinc have demonstrated their ability to align carbon nanotubes into micro-scale networks with an unusual “rings-and-rods” pattern. This paper investigates how the compounds interact with pristine and functionalized graphene using density functional theory calculations and molecular dynamic simulations. Using the free energy perturbation method we will show how the addition of phenyl side groups to the core compound and functionalization of graphene affect the stability, mobility and conformation adopted by a dimer of bis-(Zn)salphen compound adsorbed on graphene surface and what it can reveal about the arrangement of chains of bis-(Zn)salphen polymer around carbon nanotubes during the self-assembly of microscale networks.

Funder

Portuguese Foundation for Science and Technology (FCT) in the framework of the Strategic Funding

SATRAP

SATRAP-PLUS

Publisher

MDPI AG

Subject

Polymers and Plastics,General Chemistry

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