Author
Listed:
- Young-Ik Sohn
(Harvard University)
- Srujan Meesala
(Harvard University)
- Benjamin Pingault
(University of Cambridge)
- Haig A. Atikian
(Harvard University)
- Jeffrey Holzgrafe
(Harvard University
University of Cambridge)
- Mustafa Gündoğan
(University of Cambridge)
- Camille Stavrakas
(University of Cambridge)
- Megan J. Stanley
(University of Cambridge)
- Alp Sipahigil
(Harvard University)
- Joonhee Choi
(Harvard University
Harvard University)
- Mian Zhang
(Harvard University)
- Jose L. Pacheco
(Sandia National Laboratories)
- John Abraham
(Sandia National Laboratories)
- Edward Bielejec
(Sandia National Laboratories)
- Mikhail D. Lukin
(Harvard University)
- Mete Atatüre
(University of Cambridge)
- Marko Lončar
(Harvard University)
Abstract
The uncontrolled interaction of a quantum system with its environment is detrimental for quantum coherence. For quantum bits in the solid state, decoherence from thermal vibrations of the surrounding lattice can typically only be suppressed by lowering the temperature of operation. Here, we use a nano-electro-mechanical system to mitigate the effect of thermal phonons on a spin qubit – the silicon-vacancy colour centre in diamond – without changing the system temperature. By controlling the strain environment of the colour centre, we tune its electronic levels to probe, control, and eventually suppress the interaction of its spin with the thermal bath. Strain control provides both large tunability of the optical transitions and significantly improved spin coherence. Finally, our findings indicate the possibility to achieve strong coupling between the silicon-vacancy spin and single phonons, which can lead to the realisation of phonon-mediated quantum gates and nonlinear quantum phononics.
Suggested Citation
Young-Ik Sohn & Srujan Meesala & Benjamin Pingault & Haig A. Atikian & Jeffrey Holzgrafe & Mustafa Gündoğan & Camille Stavrakas & Megan J. Stanley & Alp Sipahigil & Joonhee Choi & Mian Zhang & Jose L., 2018.
"Controlling the coherence of a diamond spin qubit through its strain environment,"
Nature Communications, Nature, vol. 9(1), pages 1-6, December.
Handle:
RePEc:nat:natcom:v:9:y:2018:i:1:d:10.1038_s41467-018-04340-3
DOI: 10.1038/s41467-018-04340-3
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