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Autori principali: You, Manqi, He, Chaoyu, Guo, Gencai, Zhong, Jianxin
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2501.14318
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author You, Manqi
He, Chaoyu
Guo, Gencai
Zhong, Jianxin
author_facet You, Manqi
He, Chaoyu
Guo, Gencai
Zhong, Jianxin
contents Color centers are vital for quantum information processing, but traditional ones often suffer from instability, difficulty in realization, and precise control of locations. In contrast, natural intrinsic vacancy-based color centers in two-dimensional systems offer enhanced stability and tunability. In this work, we demonstrate that g-C$_3$N$_4$ with natural intrinsic vacancies is highly suitable for trapping B/C atoms to form stable color centers as qubits. With easily identifiable vacancies, B/C atoms are expectable to be placed at the vacancy sites in g-C$_3$N$_4$ through STM manipulation. The vacancy sites are confirmed as the most stable adsorption positions, and once atoms are adsorbed, they are protected by diffusion barriers from thermal diffusions. The most stable charge states are C$_V^{+2}$/B$_V^{+2}$, C$_V^{+1}$/B$_V^{+1}$, and C$_V^0$/B$_V^0$ in turn, with charge transition levels of 0.39 eV and 2.49 eV, respectively. Specifically, the defect levels and net spin of C$_V$/B$_V$ can be adjusted by charge states. C$_V$, C$_V^{+1}$, C$_V^{+2}$, B$_V^{+1}$, and B$_V^{+2}$ exhibit optically allowable defect transition levels. The zero-phonon lines suggest fluorescence wavelengths fall within the mid-infrared band, ideal for qubit operations of stable initialization and readout. Furthermore, the Zero-field splitting (ZFS) parameter and the characteristic hyperfine tensor are provided as potential fingerprints for electron paramagnetic resonance (EPR) experiments.
format Preprint
id arxiv_https___arxiv_org_abs_2501_14318
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Natural and Intrinsic Vacancies in two-dimensional g-C$_3$N$_4$ for Trapping Isolated B and C Atoms as Color Centers
You, Manqi
He, Chaoyu
Guo, Gencai
Zhong, Jianxin
Mesoscale and Nanoscale Physics
Applied Physics
Color centers are vital for quantum information processing, but traditional ones often suffer from instability, difficulty in realization, and precise control of locations. In contrast, natural intrinsic vacancy-based color centers in two-dimensional systems offer enhanced stability and tunability. In this work, we demonstrate that g-C$_3$N$_4$ with natural intrinsic vacancies is highly suitable for trapping B/C atoms to form stable color centers as qubits. With easily identifiable vacancies, B/C atoms are expectable to be placed at the vacancy sites in g-C$_3$N$_4$ through STM manipulation. The vacancy sites are confirmed as the most stable adsorption positions, and once atoms are adsorbed, they are protected by diffusion barriers from thermal diffusions. The most stable charge states are C$_V^{+2}$/B$_V^{+2}$, C$_V^{+1}$/B$_V^{+1}$, and C$_V^0$/B$_V^0$ in turn, with charge transition levels of 0.39 eV and 2.49 eV, respectively. Specifically, the defect levels and net spin of C$_V$/B$_V$ can be adjusted by charge states. C$_V$, C$_V^{+1}$, C$_V^{+2}$, B$_V^{+1}$, and B$_V^{+2}$ exhibit optically allowable defect transition levels. The zero-phonon lines suggest fluorescence wavelengths fall within the mid-infrared band, ideal for qubit operations of stable initialization and readout. Furthermore, the Zero-field splitting (ZFS) parameter and the characteristic hyperfine tensor are provided as potential fingerprints for electron paramagnetic resonance (EPR) experiments.
title Natural and Intrinsic Vacancies in two-dimensional g-C$_3$N$_4$ for Trapping Isolated B and C Atoms as Color Centers
topic Mesoscale and Nanoscale Physics
Applied Physics
url https://arxiv.org/abs/2501.14318