Electro-mechanical control of an optical emitter using graphene

Active, in situ control of light at the nanoscale remains a challenge in modern physics and in nanophotonics in particular. A promising approach is to take advantage of the technological maturity of nano-electromechanical systems (NEMS) and to combine it with on-chip optics. However, in scaling down the dimensions of such integrated devices, the coupling of a NEMS to optical fields becomes challenging. Despite recent progress in nano-optomechanical coupling, active control of optical fields at the nanoscale has not been achieved with an on-chip NEMS thus far. Here, we show a new type of hybrid system, which consists of an on-chip graphene NEMS suspended a few tens of nanometers above nitrogen-vacancy centres (NVC), which are stable single photon emitters embedded in nano-diamonds. Electromechanical control of the photons emitted by the NVC is provided by electrostatic tuning of the graphene NEMS position, which is transduced to a modulation of NVC emission intensity. The optomechanical coupling between the graphene displacement and the NVC emission is based on near-field dipole-dipole interaction. This class of optomechanical coupling increases strongly for smaller distances, making it suitable for devices with nanoscale dimensions. These achievements hold promise for the selective control of single-emitter arrays on chip, optical spectroscopy of individual nano-objects, integrated optomechanical information processing and quantum optomechanics.

[1]  A. Mahmood,et al.  Distance dependence of the energy transfer rate from a single semiconductor nanostructure to graphene. , 2015, Nano letters.

[2]  C. W. Wong,et al.  Photon transport enhanced by transverse Anderson localization in disordered superlattices , 2014, Nature Physics.

[3]  H. Riedmatten,et al.  Electrical control of optical emitter relaxation pathways enabled by graphene , 2014, Nature Physics.

[4]  Laurens Kuipers,et al.  Mapping nanoscale light fields , 2014, Nature Photonics.

[5]  W. Pernice Circuit optomechanics: concepts and materials , 2014, IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control.

[6]  G. Brawley,et al.  Evanescent-Field Optical Readout of Graphene Mechanical Motion at Room Temperature , 2014, 1408.1281.

[7]  G. Navickaite,et al.  Single-molecule study for a graphene-based nano-position sensor , 2014, 1407.6951.

[8]  P. Appel,et al.  Strain coupling of a nitrogen-vacancy center spin to a diamond mechanical oscillator. , 2014, Physical review letters.

[9]  Martin Heiss,et al.  Quantum dot opto-mechanics in a fully self-assembled nanowire. , 2014, Nano letters.

[10]  J. Güttinger,et al.  Coupling graphene mechanical resonators to superconducting microwave cavities. , 2014, Nano letters.

[11]  A Auffèves,et al.  Strain-mediated coupling in a quantum dot-mechanical oscillator hybrid system. , 2013, Nature nanotechnology.

[12]  Maciej Lewenstein,et al.  Harnessing vacuum forces for quantum sensing of graphene motion. , 2013, Physical review letters.

[13]  Vibhor Singh,et al.  Deterministic transfer of two-dimensional materials by all-dry viscoelastic stamping , 2013, 1311.4829.

[14]  Patrik Rath,et al.  Diamond-integrated optomechanical circuits , 2013, Nature Communications.

[15]  Neil B. Manson,et al.  The nitrogen-vacancy colour centre in diamond , 2013, 1302.3288.

[16]  F. Koppens,et al.  Universal distance-scaling of nonradiative energy transfer to graphene. , 2013, Nano letters.

[17]  F. Reinhard,et al.  Single defect center scanning near-field optical microscopy on graphene. , 2013, Nano letters.

[18]  Brahim Lounis,et al.  Single molecule detection of nanomechanical motion. , 2012, Physical review letters.

[19]  J. Rarity,et al.  Photonic quantum technologies , 2009, 1003.3928.

[20]  A. N. Grigorenko,et al.  Graphene plasmonics , 2012, Nature Photonics.

[21]  Patrick Maletinsky,et al.  Integrated diamond networks for quantum nanophotonics. , 2011, Nano letters.

[22]  T. Stauber,et al.  Fluorescence quenching in graphene: A fundamental ruler and evidence for transverse plasmons , 2011, 1108.1160.

[23]  M. Aspelmeyer,et al.  Laser cooling of a nanomechanical oscillator into its quantum ground state , 2011, Nature.

[24]  Nader Engheta,et al.  Transformation Optics Using Graphene , 2011, Science.

[25]  Xiang Zhang,et al.  A graphene-based broadband optical modulator , 2011, Nature.

[26]  J. Chaste,et al.  Nonlinear damping in mechanical resonators made from carbon nanotubes and graphene. , 2011, Nature nanotechnology.

[27]  F. J. Garcia-Vidal,et al.  Fields radiated by a nanoemitter in a graphene sheet , 2011, 1104.3558.

[28]  F. Koppens,et al.  Graphene plasmonics: a platform for strong light-matter interactions. , 2011, Nano letters.

[29]  P. Zoller,et al.  A quantum spin transducer based on nanoelectromechanical resonator arrays , 2009, 0908.0316.

[30]  T. Kippenberg,et al.  Near-field cavity optomechanics with nanomechanical oscillators , 2009, CLEO/QELS: 2010 Laser Science to Photonic Applications.

[31]  P. Kim,et al.  Performance of monolayer graphene nanomechanical resonators with electrical readout. , 2009, Nature nanotechnology.

[32]  T. Baehr‐Jones,et al.  Harnessing optical forces in integrated photonic circuits , 2008, Nature.

[33]  A. Shields Semiconductor quantum light sources , 2007, 0704.0403.

[34]  Scott S. Verbridge,et al.  Electromechanical Resonators from Graphene Sheets , 2007, Science.

[35]  M. Lipson,et al.  All-optical control of light on a silicon chip , 2004, Nature.