Intermolecular Interactions between Serine and C60, C59Si, and C59Ge: a DFT Study

The study of intermolecular interactions is of great importance. This study attempted to quantitatively examine the interactions between Serine (C3H7NO3) and fullerene nanocages, C-60, in vacuum. As the frequent introduction of elements as impurities into the structure of nanomaterials can increase the intensity of intermolecular interactions, nanocages doped with silicon and germanium have also been studied as adsorbents, C59Si and C59Ge. Quantum mechanical studies of such systems are possible in the density functional theory (DFT) framework. For this purpose, various functionals, such as B3LYP-D3, omega B97XD, and M062X, have been used. One of the most suitable basis functionals for the systems studied in this research is 6-311G (d), which has been used in both optimization calculations and calculations related to wave function analyses. The main part of this work is the study of various analyses that reveal the nature of the intermolecular interactions between the two components introduced above. The results of conceptual DFT, natural bond orbital, non-covalent interactions, and quantum theory of atoms in molecules were consistent and in favor of physical adsorption in all systems. Germanium had more adsorption energy than other dopants. The HOMO-LUMO energy gaps were as follows: C-60: 5.996, C59Si: 5.309 and C59Ge: 5.188 eV at B3LYP-D3/6-311 G (d) model chemistry. The sensitivity of the adsorption increased when an amino acid molecule interacted with doped C-60, and this capability could be used to design nanocarrier to detect Serine amino acid.

Automated summary

The study aimed to quantitatively examine the interactions between Serine and fullerene nanocages C-60, as well as doped nanocages C59Si and C59Ge. Quantum mechanical studies using density functional theory framework were conducted, revealing that germanium had higher adsorption energy and increased sensitivity when interacting with an amino acid molecule.