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A p-orbital honeycomb-Kagome lattice realized in a two-dimensional metal-organic framework

Xiaobo Wang, Bowen Xia, Cheng‐Kun Lyu, Dongwook Kim, En Li, Shuqing Fu, Jiayan Chen, Pei Nian Liu, Feng Liu, Nian Lin

2023Communications Chemistry19 citationsDOIOpen Access PDF

Abstract

The experimental realization of p-orbital systems is desirable because p-orbital lattices have been proposed theoretically to host strongly correlated electrons that exhibit exotic quantum phases. Here, we synthesize a two-dimensional Fe-coordinated bimolecular metal-organic framework which constitutes a honeycomb lattice of 1,4,5,8,9,12-hexaazatriphenylene molecules and a Kagome lattice of 5,15-di(4-pyridyl)-10,20-diphenylporphyrin molecules on a Au(111) substrate. Density-functional theory calculations show that the framework features multiple well-separated spin-polarized Kagome bands, namely Dirac cone bands and Chern flat bands, near the Fermi level. Using tight-binding modelling, we reveal that these bands are originated from two effects: the low-lying molecular orbitals that exhibit p-orbital characteristics and the honeycomb-Kagome lattice. This study demonstrates that p-orbital Kagome bands can be realized in metal-organic frameworks by using molecules with molecular orbitals of p-orbital like symmetry.

Topics & Concepts

Atomic orbitalPhysicsMolecular orbitalNon-bonding orbitalLattice (music)Orbital hybridisationMoleculeDensity functional theoryCondensed matter physicsMolecular physicsChemistryChemical physicsElectronMolecular orbital theoryQuantum mechanicsAcousticsAdvanced Condensed Matter PhysicsTopological Materials and PhenomenaTheoretical and Computational Physics
A p-orbital honeycomb-Kagome lattice realized in a two-dimensional metal-organic framework | Litcius