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Self‐Organized Kagomé‐Lattice in a Conductive Metal‐Organic Monolayer

Nesrine Shaiek, Hassan Denawi, Mathieu Koudia, R. Hayn, Steffen Schäfer, Isabelle Berbézier, Chokri Lamine, Olivier Siri, A. Akremi, Mathieu Abel

2022Advanced Materials Interfaces17 citationsDOIOpen Access PDF

Abstract

Abstract The on‐surface synthesis of metal‐organic covalent coordination networks with a dense Kagomé lattice of metallic centers is reported. Tetrahydroxyquinone and metal atoms (M = Cu or Mn) are codeposited on Ag(111) substrate to build well‐ordered 2D lattices M 3 C 6 O 6 . The surface is studied by scanning tunneling microscopy, low‐energy electron diffraction, and X‐ray photoelectron spectroscopy (XPS). Density functional theory (DFT) reveals a Cu + charge state and no local magnetic moments for the Cu‐organic network. For the Mn‐organic network, the charge state Mn 2+ and a local spin S = 5/2 are found. Charge transfer stabilizes the Cu + and Mn 2+ charge states. DFT calculations show a Dirac point, i.e., a band crossing with linear electron dispersion at the K‐point of the Brillouin zone. This Dirac point is at the Fermi level without charge transfer but drops by 100 meV if electron doping of Cu 3 C 6 O 6 on Ag(111) surface is acknowledged. The magnetic couplings of an isolated Mn 3 C 6 O 6 monolayer to be short range and antiferromagnetic leading to high frustration at the Kagomé lattice and a tendency toward a spin‐liquid ground state are predicted. In the case of hole transfer from the substrate, ferromagnetic ordering is introduced, making Mn 3 C 6 O 6 an interesting candidate for the quantum anomalous Hall effect.

Topics & Concepts

AntiferromagnetismCondensed matter physicsMaterials scienceBrillouin zoneX-ray photoelectron spectroscopyGround stateFermi levelFerromagnetismMonolayerScanning tunneling microscopePhotoemission spectroscopyElectronPhysicsNanotechnologyNuclear magnetic resonanceAtomic physicsQuantum mechanicsAdvanced Condensed Matter PhysicsTopological Materials and PhenomenaQuantum and electron transport phenomena
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