Litcius/Paper detail

Accurate measurement of atomic magnetic moments by minimizing the tip magnetic field in STM-based electron paramagnetic resonance

Tom S. Seifert, Štěpán Kovařík, Pietro Gambardella, Sebastian Stepanow

2021Physical Review Research24 citationsDOIOpen Access PDF

Abstract

Electron paramagnetic resonance (EPR) performed with a scanning tunneling microscope (STM) allows for probing the spin excitation of single atomic species with MHz energy resolution. One of the basic applications of conventional EPR is the precise determination of magnetic moments. However, in an STM, the local magnetic fields of the spin-polarized tip can introduce systematic errors in the measurement of the magnetic moments by EPR. We propose to solve this issue by finding tip-sample distances at which the EPR resonance shift caused by the magnetic field of the tip is minimized. To this end, we measure the dependence of the resonance field on the tip-sample distance at different radiofrequencies and identify specific distances for which the true magnetic moment is found. Additionally, we show that the tip's influence can be averaged out by using magnetically bistable tips, which provides a complementary method to accurately measure the magnetic moment of surface atoms using EPR STM.

Topics & Concepts

Electron paramagnetic resonanceMagnetic momentMagnetic resonance force microscopyMagnetic fieldExcitationParamagnetismCondensed matter physicsElectron magnetic dipole momentPulsed EPRAtomic physicsResonance (particle physics)Spin (aerodynamics)Scanning tunneling microscopeChemistryPhysicsMagnetizationNuclear magnetic resonanceFerromagnetic resonanceMagnetic resonance imagingSpin echoQuantum mechanicsThermodynamicsRadiologyMedicineQuantum and electron transport phenomenaMechanical and Optical ResonatorsMolecular Junctions and Nanostructures