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Journal Article

Atomic-scale sensing of the magnetic dipolar field from single atoms

MPS-Authors

Rolf-Pissarczyk,  S.
Max Planck Society;

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Citation

Choi, T., Paul, W., Rolf-Pissarczyk, S., Macdonald, A., Natterer, F., Yang, K., et al. (2017). Atomic-scale sensing of the magnetic dipolar field from single atoms. Nature Nanotechnology, 12(5), 420-424.


Cite as: https://hdl.handle.net/21.11116/0000-000E-D512-D
Abstract
Spin resonance provides the high-energy resolution needed to determine biological and material structures by sensing weak magnetic interactions(1). In recent years, there have been notable achievements in detecting(2) and coherently controlling(3-7) individual atomic-scale spin centres for sensitive local magnetometry(8-10). However, positioning the spin sensor and characterizing spin-spin interactions with sub-nanometre precision have remained outstanding challenges(11,12). Here, we use individual Fe atoms as an electron spin resonance (ESR) sensor in a scanning tunnelling microscope to measure the magnetic field emanating from nearby spins with atomic-scale precision. On artificially built assemblies of magnetic atoms (Fe and Co) on a magnesium oxide surface, we measure that the interaction energy between the ESR sensor and an adatom shows an inverse-cube distance dependence (r(-3.01+/-0.04)). This demonstrates that the atoms are predominantly coupled by the magnetic dipole-dipole interaction, which, according to our observations, dominates for atom separations greater than 1 nm. This dipolar sensor can determine the magnetic moments of individual adatoms with high accuracy. The achieved atomic-scale spatial resolution in remote sensing of spins may ultimately allow the structural imaging of individual magnetic molecules, nanostructures and spin-labelled biomolecules.