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- Title
Quantum capacitance mediated carbon nanotube optomechanics.
- Authors
Blien, Stefan; Steger, Patrick; Hüttner, Niklas; Graaf, Richard; Hüttel, Andreas K.
- Abstract
Cavity optomechanics allows the characterization of a vibration mode, its cooling and quantum manipulation using electromagnetic fields. Regarding nanomechanical as well as electronic properties, single wall carbon nanotubes are a prototypical experimental system. At cryogenic temperatures, as high quality factor vibrational resonators, they display strong interaction between motion and single-electron tunneling. Here, we demonstrate large optomechanical coupling of a suspended carbon nanotube quantum dot and a microwave cavity, amplified by several orders of magnitude via the nonlinearity of Coulomb blockade. From an optomechanically induced transparency (OMIT) experiment, we obtain a single photon coupling of up to g0 = 2π ⋅ 95 Hz. This indicates that normal mode splitting and full optomechanical control of the carbon nanotube vibration in the quantum limit is reachable in the near future. Mechanical manipulation and characterization via the microwave field can be complemented by the manifold physics of quantum-confined single electron devices. Carbon nanotube mechanical resonators are difficult to couple optomechanically to microwave fields. Here, the authors exploit Coulomb blockade's nonlinearity to amplify the single photon coupling between a suspended carbon nanotube quantum dot and a microwave cavity by several orders of magnitude.
- Subjects
OPTOMECHANICS; COULOMB blockade; ELECTROMAGNETIC fields; CAVITY resonators; QUALITY factor; ELECTRIC capacity
- Publication
Nature Communications, 2020, Vol 11, Issue 1, p1
- ISSN
2041-1723
- Publication type
Article
- DOI
10.1038/s41467-020-15433-3