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Mapping Orbital-Resolved Magnetism in Single Lanthanide Atoms

Aparajita Singha, Daria Sostina, Christoph Wolf, Safa L. Ahmed, Denis S. Krylov, Luciano Colazzo, Pierluigi Gargiani, Stefano Agrestini, Woo-Suk Noh, Jae‐Hoon Park, Marina Pivetta, S. Rusponi, Harald Brune, Andreas J. Heinrich, A. Barla, Fabio Donati

2021ACS Nano17 citationsDOIOpen Access PDF

Abstract

Single lanthanide atoms and molecules are promising candidates for atomic data storage and quantum logic due to the long lifetime of their magnetic quantum states. Accessing and controlling these states through electrical transport requires precise knowledge of their electronic configuration at the level of individual atomic orbitals, especially of the outer shells involved in transport. However, no experimental techniques have so far shown the required sensitivity to probe single atoms with orbital selectivity. Here we resolve the magnetism of individual orbitals in Gd and Ho single atoms on MgO/Ag(100) by combining X-ray magnetic circular dichroism with multiplet calculations and density functional theory. In contrast to the usual assumption of bulk-like occupation of the different electronic shells, we establish a charge transfer mechanism leading to an unconventional singly ionized configuration. Our work identifies the role of the valence electrons in determining the quantum level structure and spin-dependent transport properties of lanthanide-based nanomagnets.

Topics & Concepts

LanthanideMagnetismDensity functional theoryAtomic orbitalValence (chemistry)Electronic structureElectron configurationAtomic physicsMagnetic circular dichroismMolecular orbitalMaterials scienceMagnetic momentElectronChemistryChemical physicsCondensed matter physicsPhysicsMoleculeComputational chemistryIonQuantum mechanicsOrganic chemistrySpectral lineMagnetism in coordination complexesLanthanide and Transition Metal ComplexesAdvanced NMR Techniques and Applications
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