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Engineering atomic-scale magnetic fields by dysprosium single atom magnets

Aparajita Singha, Philip Willke, Tobias Bilgeri, Xue Zhang, Harald Brune, Fabio Donati, Andreas J. Heinrich, Taeyoung Choi

2021Nature Communications62 citationsDOIOpen Access PDF

Abstract

Atomic scale engineering of magnetic fields is a key ingredient for miniaturizing quantum devices and precision control of quantum systems. This requires a unique combination of magnetic stability and spin-manipulation capabilities. Surface-supported single atom magnets offer such possibilities, where long temporal and thermal stability of the magnetic states can be achieved by maximizing the magnet/ic anisotropy energy (MAE) and by minimizing quantum tunnelling of the magnetization. Here, we show that dysprosium (Dy) atoms on magnesium oxide (MgO) have a giant MAE of 250 meV, currently the highest among all surface spins. Using a variety of scanning tunnelling microscopy (STM) techniques including single atom electron spin resonance (ESR), we confirm no spontaneous spin-switching in Dy over days at ≈ 1 K under low and even vanishing magnetic field. We utilize these robust Dy single atom magnets to engineer magnetic nanostructures, demonstrating unique control of magnetic fields with atomic scale tunability.

Topics & Concepts

DysprosiumMagnetizationQuantum tunnellingMagnetic fieldMaterials scienceAtomic unitsCondensed matter physicsMagnetic anisotropyMagnetAtom (system on chip)SpinsAtomic physicsPhysicsEmbedded systemComputer scienceQuantum mechanicsNuclear physicsQuantum and electron transport phenomenaMagnetism in coordination complexesMagnetic properties of thin films