Nuclear Spin Quantum Memory in Silicon Carbide

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Tissot_2-16hlcn7t9k47h7.pdf(697.96 KB)
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2022
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Trupke, Michael
Koller, Philipp
Astner, Thomas
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urn:nbn:de:bsz:352-2-16hlcn7t9k47h7
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10.1103/PhysRevResearch.4.033107
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2204.09295v2
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862721
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Physical Review Research ; 4 (2022), 3. - 033107. - American Physical Society. - eISSN 2643-1564
Abstract
Transition metal (TM) defects in silicon carbide (SiC) are a promising platform for applications in quantum technology. Some TM defects, e.g. vanadium, emit in one of the telecom bands, but the large ground state hyperfine manifold poses a problem for applications which require pure quantum states. We develop a driven, dissipative protocol to polarize the nuclear spin, based on a rigorous theoretical model of the defect. We further show that nuclear-spin polarization enables the use of well-known methods for initialization and long-time coherent storage of quantum states. The proposed nuclear-spin preparation protocol thus marks the first step towards an all-optically controlled integrated platform for quantum technology with TM defects in SiC.
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ISO 690TISSOT, Benedikt, Michael TRUPKE, Philipp KOLLER, Thomas ASTNER, Guido BURKARD, 2022. Nuclear Spin Quantum Memory in Silicon Carbide. In: Physical Review Research. American Physical Society. 4(3), 033107. eISSN 2643-1564. Available under: doi: 10.1103/PhysRevResearch.4.033107
BibTex
@article{Tissot2022-04-20T08:23:26ZNucle-58282,
  year={2022},
  doi={10.1103/PhysRevResearch.4.033107},
  title={Nuclear Spin Quantum Memory in Silicon Carbide},
  number={3},
  volume={4},
  journal={Physical Review Research},
  author={Tissot, Benedikt and Trupke, Michael and Koller, Philipp and Astner, Thomas and Burkard, Guido},
  note={Article Number: 033107}
}
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