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Scanning spin probe based on magnonic vortex quantum cavities

Authors :
National Science Foundation (US)
European Commission
European Research Council
Agencia Estatal de Investigación (España)
Ministerio de Ciencia, Innovación y Universidades (España)
Ministerio de Ciencia e Innovación (España)
Gobierno de Aragón
Department of Energy (US)
Consejo Superior de Investigaciones Científicas (España)
González-Gutiérrez, Carlos A.
García-Pons, David
Zueco, David
Martínez Pérez, M. J.
National Science Foundation (US)
European Commission
European Research Council
Agencia Estatal de Investigación (España)
Ministerio de Ciencia, Innovación y Universidades (España)
Ministerio de Ciencia e Innovación (España)
Gobierno de Aragón
Department of Energy (US)
Consejo Superior de Investigaciones Científicas (España)
González-Gutiérrez, Carlos A.
García-Pons, David
Zueco, David
Martínez Pérez, M. J.
Publication Year :
2024

Abstract

Performing nanoscale scanning electron paramagnetic resonance (EPR) requires three essential ingredients: First, a static magnetic field together with field gradients to Zeeman split the electronic energy levels with spatial resolution; second, a radio frequency (rf) magnetic field capable of inducing spin transitions; finally, a sensitive detection method to quantify the energy absorbed by spins. This is usually achieved by combining externally applied magnetic fields with inductive coils or cavities, fluorescent defects, or scanning probes. Here, we theoretically propose the realization of an EPR scanning sensor merging all three characteristics into a single device: the vortex core stabilized in ferromagnetic thin-film discs. On one hand, the vortex ground state generates a significant static magnetic field and field gradients. On the other hand, the precessional motion of the vortex core around its equilibrium position produces a circularly polarized oscillating magnetic field, which is enough to produce spin transitions. Finally, the spin–magnon coupling broadens the vortex gyrotropic frequency, suggesting a direct measure of the presence of unpaired electrons. Moreover, the vortex core can be displaced by simply using external magnetic fields of a few mT, enabling EPR scanning microscopy with large spatial resolution. Our numerical simulations show that, by using low damping magnets, it is theoretically possible to detect single spins located on the disc’s surface. Vortex nanocavities could also attain strong coupling to individual spin molecular qubits with potential applications to mediate qubit–qubit interactions or to implement qubit readout protocols.

Details

Database :
OAIster
Notes :
English
Publication Type :
Electronic Resource
Accession number :
edsoai.on1431968694
Document Type :
Electronic Resource