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Highly stable two-dimensional metal-carbon monolayer with interpenetrating honeycomb structures

Shulong Li, Kah Meng Yam, Na Guo, Yong Zhao, Chun Zhang

2021npj 2D Materials and Applications23 citationsDOIOpen Access PDF

Abstract

Abstract With the ongoing effort in proposing and realizing functional two-dimensional (2D) materials, we predict by first-principles calculations a family of 2D metal-carbon (M–C) crystals consisting of M–C trigonal lattice interpenetrated with the metal buckled honeycomb structure. We suggest by simulations that the 2D M–C crystals can be readily fabricated by a self-organizing lattice reconstruction process after placing metal atoms on hollow sites of γ-graphyne. In total, we found 12 members of the family and they exhibit a variety of electronic and magnetic properties. In this work, we highlight and focus on the Fe member of the family, 2D-Fe 2 C 12 . Each Fe in 2D-Fe 2 C 12 has a magnetic moment of 1 μ B due to the spin splitting of Fe E1 bands at Fermi surface, resulting in half metallicity and high catalytic activity with unusually high-density single-atom Fe active sites. Ab initio molecular dynamics simulations revealed that the 2D-Fe 2 C 12 retains its structural integrity up to 700 K of simulated short duration annealing. We expect these results to stimulate experimental research for the 2D M–C crystals we proposed.

Topics & Concepts

GraphyneMaterials scienceMonolayerMetalMagnetic momentCrystallographyFermi levelDensity functional theoryLattice (music)Ab initioElectronic structureAnnealing (glass)Chemical physicsCondensed matter physicsNanotechnologyComputational chemistryChemistryGrapheneComposite materialPhysicsOrganic chemistryElectronAcousticsQuantum mechanicsMetallurgyGraphene research and applicationsMXene and MAX Phase Materials2D Materials and Applications
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