Optomechanical coupling between a multilayer graphene mechanical resonator and a superconducting microwave cavity

Nature Nanotechnology

Volumn 9, Issue 10, 2014, Pages 820-824

  Singh, V ^a   Bosman, S J ^a   Schneider, B H ^a   Blanter, Y M ^a   Castellanos Gomez, A ^a   Steele, G A ^a  

^a DELFT UNIVERSITY OF TECHNOLOGY   (Netherlands)

Author keywords

[No Author keywords available]

Indexed keywords

CAVITY RESONATORS; GRAPHENE; GROUND STATE; MICROWAVES; MULTILAYERS; OPTOMECHANICS; SUPERCONDUCTING RESONATORS; THERMOMECHANICAL TREATMENT;

MECHANICAL RESONATORS; MICROWAVE AMPLIFICATION; POSITION SENSITIVITY; QUANTUM GROUND STATE; SUPERCONDUCTING CAVITIES; SUPERCONDUCTING MICROWAVE CAVITY; THERMOMECHANICAL NOISE; TWO-DIMENSIONAL CRYSTALS;

MICROWAVE RESONATORS;

GRAPHENE;

ABSORPTION; ARTICLE; CALIBRATION; CONDUCTANCE; MICROWAVE RADIATION; NOISE; PHOTON; PRIORITY JOURNAL; QUANTUM MECHANICS; SENSITIVITY ANALYSIS; STRENGTH; SUPERCONDUCTOR;

EID: 84909966777     PISSN: 17483387     EISSN: 17483395     Source Type: Journal    
DOI: 10.1038/nnano.2014.168     Document Type: Article

References (26)

1. Bunch, J. S. et al. Electromechanical resonators from graphene sheets. Science 315, 490-493 (2007).
2. Chen, C. et al. Performance of monolayer graphene nanomechanical resonators with electrical readout. Nature Nanotech. 4, 861-867 (2009).
3. Singh, V. et al. Probing thermal expansion of graphene and modal dispersion at low-Temperature using graphene nanoelectromechanical systems resonators. Nanotechnology 21, 165204 (2010).
4. Barton, R. A. et al. High, size-dependent quality factor in an array of graphene mechanical resonators. Nano Lett. 11, 1232-1236 (2011).
5. Eichler, A. et al. Nonlinear damping in mechanical resonators made from carbon nanotubes and graphene. Nature Nanotech. 6, 339-342 (2011).
6. Song, X. et al. Stamp transferred suspended graphene mechanical resonators for radio frequency electrical readout. Nano Lett. 12, 198-202 (2012).
7. Barton, R. A. et al. Photothermal self-oscillation and laser cooling of graphene optomechanical systems. Nano Lett. 12, 4681-4686 (2012).
8. Chen, C. et al. Graphene mechanical oscillators with tunable frequency. Nature Nanotech. 8, 923-927 (2013).
9. Regal, C. A., Teufel, J. D. & Lehnert, K. W. Measuring nanomechanical motion with a microwave cavity interferometer. Nature Phys. 4, 555-560 (2008).
10. Teufel, J. D., Donner, T., Castellanos-Beltran, M. A., Harlow, J. W. & Lehnert, K. W. Nanomechanical motion measured with an imprecision below that at the standard quantum limit. Nature Nanotech. 4, 820-823 (2009).
11. Rocheleau, T. et al. Preparation and detection of a mechanical resonator near the ground state of motion. Nature 463, 72-75 (2010).
12. Teufel, J. D. et al. Circuit cavity electromechanics in the strong-coupling regime. Nature 471, 204-208 (2011).
13. Massel, F. et al. Microwave amplification with nanomechanical resonators. Nature 480, 351-354 (2011).
14. Hocke, F. et al. Electromechanically induced absorption in a circuit nanoelectromechanical system. New J. Phys. 14, 123037 (2012).
15. Teufel, J. D. et al. Sideband cooling of micromechanical motion to the quantum ground state. Nature 475, 359-363 (2011).
16. Palomaki, T. A., Teufel, J. D., Simmonds, R. W. & Lehnert, K. W. Entangling mechanical motion with microwave fields. Science 342, 710-713 (2013).
17. Agarwal, G. S. & Huang, S. Electromagnetically induced transparency in mechanical effects of light. Phys. Rev. A 81, 041803 (2010).
18. Weis, S. et al. Optomechanically induced transparency. Science 330, 1520-1523 (2010).
19. Safavi-Naeini, A. H. et al. Electromagnetically induced transparency and slow light with optomechanics. Nature 472, 69-73 (2011).
20. Aspelmeyer, M., Kippenberg, T. J. & Marquardt, F. Cavity optomechanics. Preprint at http://arXiv.org/abs/1303.0733. Accepted in Rev. Mod. Phys. (2014).
21. Chan, J. et al. Laser cooling of a nanomechanical oscillator into its quantum ground state. Nature 478, 89-92 (2011).
22. Castellanos-Gomez, A. et al. Deterministic transfer of two-dimensional materials by all-dry viscoelastic stamping. 2D Materials 1, 011002 (2014).
23. Zhou, X. et al. Slowing, advancing and switching of microwave signals using circuit nanoelectromechanics. Nature Phys. 9, 179-184 (2013).
24. Gorodetsky, M. L., Schliesser, A., Anetsberger, G., Deleglise, S. & Kippenberg, T. J. Determination of the vacuum optomechanical coupling rate using frequency noise calibration. Opt. Express 18, 23236-23246 (2010).
25. Weiss, T., Bruder, C. & Nunnenkamp, A. Strong-coupling effects in dissipatively coupled optomechanical systems. New J. Phys. 15, 045017 (2013).
26. Elste, F., Girvin, S. M. & Clerk, A. A. Quantum noise interference and backaction cooling in cavity nanomechanics. Phys. Rev. Lett. 102, 207209 (2009).