Interacting donor-acceptor pairs in hBN, with separations controlling charge transfer and spin coupling, produce the observed coupled spin-optical signals including modulated zero-phonon lines and ODMR contrast.
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3 Pith papers cite this work. Polarity classification is still indexing.
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Carbon defects in TMD bilayers are computationally shown to enable room-temperature defect-mediated quantum emission at telecom wavelengths with material-dependent optical fingerprints.
Carbon-nitrogen interstitial pairs and oxygen-containing complexes are identified as the likely atomic structures for the N-line series in silicon, offering isoelectronic alternatives to the T-center for spin qubits.
citing papers explorer
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Interacting donor-acceptor pairs as the origin of coupled spin-optical signals in hexagonal boron nitride
Interacting donor-acceptor pairs in hBN, with separations controlling charge transfer and spin coupling, produce the observed coupled spin-optical signals including modulated zero-phonon lines and ODMR contrast.
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Quantum Emitters at Telecommunication Wavelengths based on Carbon Defects in Transition Metal Dichalcogenides
Carbon defects in TMD bilayers are computationally shown to enable room-temperature defect-mediated quantum emission at telecom wavelengths with material-dependent optical fingerprints.
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First-principles insights into the atomic structure of carbon-nitrogen-oxygen complex color centers in silicon
Carbon-nitrogen interstitial pairs and oxygen-containing complexes are identified as the likely atomic structures for the N-line series in silicon, offering isoelectronic alternatives to the T-center for spin qubits.