Litcius/Paper detail

Atomic-scale spin-polarization maps using functionalized superconducting probes

Lucas Schneider, Philip Beck, Jens Wiebe, Roland Wiesendanger

2021Science Advances64 citationsDOIOpen Access PDF

Abstract

A scanning tunneling microscope (STM) with a magnetic tip that has a sufficiently strong spin polarization can be used to map the sample's spin structure down to the atomic scale but usually lacks the possibility to absolutely determine the value of the sample's spin polarization. Magnetic impurities in superconducting materials give rise to pairs of perfectly, i.e., 100%, spin-polarized subgap resonances. In this work, we functionalize the apex of a superconducting Nb STM tip with such impurity states by attaching Fe atoms to probe the spin polarization of atom-manipulated Mn nanomagnets on a Nb(110) surface. By comparison with spin-polarized STM measurements of the same nanomagnets using Cr bulk tips, we demonstrate an extraordinary spin sensitivity and the possibility to measure the sample's spin-polarization values close to the Fermi level quantitatively with our new functionalized probes.

Topics & Concepts

NanomagnetScanning tunneling microscopeCondensed matter physicsImpuritySuperconductivityMaterials scienceSpin polarizationSpin (aerodynamics)Spin polarized scanning tunneling microscopyFermi levelScanning tunneling spectroscopyMagnetic force microscopePolarization (electrochemistry)MicroscopeQuantum tunnellingAtomic unitsMicroscopyScanning probe microscopyAtom (system on chip)NanotechnologyMagnetic impurityElectrochemical scanning tunneling microscopeSpin statesLocal density of statesFermi energyMagnetic fieldMagnetic properties of thin filmsAtomic and Subatomic Physics ResearchTopological Materials and Phenomena