Li, Pei and Zhou, Ji-Yang and Li, Song and Udvarhelyi, Péter and Xu, Jin-Shi and Li, Chuan-Feng and Huang, Bing and Guo, Guang-Can and Gali, Ádám (2025) Non-invasive bioinert room-temperature quantum sensor from silicon carbide qubits. NATURE MATERIALS, 24. pp. 1913-1919. ISSN 1476-1122
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Text (Supplementary Notes 1–13, Tables I–IV and Figs. 1–25.)
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Text (Swinging motion of the carbon chain with the methyl group at the end of the carbon chain and a water droplet on top.)
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Text (Swinging motion of the carbon chain with the alcohol group at the end of the carbon chain and a water droplet on top.)
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Text (Swinging motion of the carbon chain with a Gd cluster.)
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Text (Source data for Fig. 1.)
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Text (Source data for Fig. 2.)
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Text (Source data for Fig. 3.)
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Text (Source data for Fig. 4.)
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Abstract
Room-temperature shallow defect spin qubits acting as a quantum sensor with favourable properties towards the biological environment are sought after, with promising impacts on bioimaging, radical detection and nanoscale nuclear spin sensing. Here we show that alkene-terminated silicon carbide hosting divacancy qubits located a few nanometres below the surface leads to a stable operation with superior sensitivity in which the host is a bioinert semiconductor with existing wafer-scale chip technology. The read-out of the qubit occurs at near-infrared wavelengths, which exhibit a minimum absorption by the organic molecules or water. We show that the divacancy qubit can realize multiple quantum sensor schemes under ambient conditions in which the suggested surface termination can be readily tailored towards the desired application. The combination of the paramount host, surface functionalization and qubit properties may significantly advance room-temperature quantum sensing, as well as provide a platform for quantum simulation and optoelectronic devices.
| Item Type: | Article |
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| Additional Information: | The online version contains supplementary material available at https://doi.org/10.1038/s41563-025-02382-9 |
| Uncontrolled Keywords: | MONOLAYERS; Chemistry, Physical; Passivation; Coherent control; Materials Science, Multidisciplinary; Physics, Applied; REACTIVE FORCE-FIELD; |
| Subjects: | Q Science / természettudomány > QC Physics / fizika |
| SWORD Depositor: | MTMT SWORD |
| Depositing User: | MTMT SWORD |
| Date Deposited: | 12 May 2026 14:15 |
| Last Modified: | 12 May 2026 14:20 |
| URI: | https://real.mtak.hu/id/eprint/238317 |
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