Quantum Electrometer for Time-Resolved Material Science at the Atomic Lattice Scale

Quantum Electrometer for Time-Resolved Material Science at the Atomic Lattice Scale

The detection of individual charges plays a crucial role in fundamental material science and the advancement of classical and quantum high-performance technologies that operate with low noise. However, resolving charges at the lattice scale in a time-resolved manner has not been achieved so far. Her...

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Veröffentlicht in:arXiv.org 2024-01
Hauptverfasser: Pieplow, Gregor, Cem Güney Torun, Munns, Joseph H D, Herrmann, Franziska Marie, Thies, Andreas, Pregnolato, Tommaso, Schröder, Tim
Format: Artikel
Sprache:eng
Schlagworte:
Diamonds
Low noise
Material properties
Noise generation
Nonlinear response
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Zusammenfassung:The detection of individual charges plays a crucial role in fundamental material science and the advancement of classical and quantum high-performance technologies that operate with low noise. However, resolving charges at the lattice scale in a time-resolved manner has not been achieved so far. Here, we present the development of an electrometer, leveraging on the spectroscopy of an optically-active spin defect embedded in a solid-state material with a non-linear Stark response. By applying our approach to diamond, a widely used platform for quantum technology applications, we successfully localize charge traps, quantify their impact on transport dynamics and noise generation, analyze relevant material properties, and develop strategies for material optimization.
ISSN:2331-8422