# Adsorption of atoms and molecules on s-triazine sheet with embedded   manganese atom: First-principles calculations

**Authors:** Yusuf Zuntu Abdullahi, Tiem Leong Yoon, Mohd Mahadi Halim, Md. Roslan, Hashim, Thong Leng Lim, and Kazuhiko Uebayash

arXiv: 1703.06466 · 2017-03-21

## TL;DR

This study uses first-principles calculations to investigate the stability, electronic, and magnetic properties of Mn-embedded s-triazine sheets with adsorbed atoms/molecules, highlighting their potential for spintronics and catalysis.

## Contribution

It provides a comprehensive analysis of Mn-C6N6 systems' properties and their modulation under external stimuli, introducing new insights into their application potential.

## Key findings

- Mn-C6N6 is structurally and mechanically stable.
- Embedding Mn preserves the semiconducting property of C6N6.
- Adsorption of O and O2 induces half-metallicity.

## Abstract

The mechanical, structural, electronic and magnetic properties of s-triazine sheet (C6N6) with embedded Mn atom (Mn-C6N6) is investigated under the influence of external environment using density functional theory. Our results show that Mn-C6N6 system is structurally and mechanically stable. The binding energy of Mn embedded in C6N6 sheet can be modulated under the influence of symmetric deformation and perpendicular electric field respectively. The semiconducting property of pure C6N6 sheet is maintained upon embedment of Mn atom in the porous site. It is also found that small increment in bi-axial tensile strain enhances the band gap (from 0.630 eV at zero strain to 0.802 eV at 5% strain) while the magnetic moment of the embedded Mn atom is preserved. The electronic and magnetic properties of the Mn-C6N6 systems are maintained up to 10 V/nm in electric field strength. We also explore the geometries, electronic and magnetic properties of Mn-C6N6 with adsorbed atoms and molecules. The Mn-C6N6 with adsorbed O atom and O2 molecule systems shows half-metallic character whereas the remaining systems preserve their semiconducting property. The total magnetic moment per unit cell in most of the systems is found to reduce as compared to that of the Mn-C6N6 sheet. The reduction in magnetic moment can be related to the strong interactions among the Mn atom and the surrounding atoms which lead to the formation of low-spin configurations. Overall, our results indicate that the Mn-C6N6 systems with and without adsorbed atoms and molecules can serve as potential candidates for future spintronics and catalysis applications.

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Source: https://tomesphere.com/paper/1703.06466