Sub-micron spin-based magnetic field imaging with an organic light emitting diode

Sub-micron spin-based magnetic field imaging with an organic light emitting diode

Quantum sensing and imaging of magnetic fields has attracted broad interests due to its potential for high sensitivity and spatial resolution. Common systems used for quantum sensing require either optical excitation (e.g., nitrogen-vacancy centres in diamond, atomic vapor magnetometers), or cryogen...

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Veröffentlicht in:arXiv.org 2022-07
Hauptverfasser: Geng, Rugang, Mena, Adrian, Pappas, William J, McCamey, Dane R
Format: Artikel
Sprache:eng
Schlagworte:
Cryogenic temperature
Diamonds
Imaging
Magnetic fields
Magnetic resonance
Magnetometers
Mapping
Organic light emitting diodes
Physics - Optics
Physics - Other Condensed Matter
Physics - Quantum Physics
Quantum sensors
Qubits (quantum computing)
Sensitivity
Spatial resolution
Virtual sensors
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Zusammenfassung:Quantum sensing and imaging of magnetic fields has attracted broad interests due to its potential for high sensitivity and spatial resolution. Common systems used for quantum sensing require either optical excitation (e.g., nitrogen-vacancy centres in diamond, atomic vapor magnetometers), or cryogenic temperatures (e.g., SQUIDs, superconducting qubits), which pose challenges for chip-scale integration and commercial scalability. Here, we demonstrate an integrated organic light emitting diode (OLED) based quantum sensor for magnetic field imaging, which employs spatially resolved magnetic resonance to provide a robust mapping of magnetic fields. By considering the monolithic OLED as an array of individual virtual sensors, we achieve sub-micron magnetic field mapping with field sensitivity of ~160 \(\mu\)T Hz\(^{-1/2}\) um\(^{-2}\). Our work demonstrates a chip-scale OLED-based laser free magnetic field sensor and an approach to magnetic field mapping built on a commercially relevant and manufacturable technology.
ISSN:2331-8422
DOI:10.48550/arxiv.2207.02479