Graphene ideal platform for nanophotonics and nanomechanics

Graphene ideal platform for nanophotonics and nanomechanics

Spanish researchers from ICFO have designed a novel type of hybrid system consisting of an on-chip graphene Nanoelectromechanical systems (NEMS) suspended a few tens of nanometres above Nitrogen-Vacancy Centres (NVCs), which are stable, single-photon emitters embedded in nanodiamonds. The scientists state that this work has confirmed that graphene ideal platform for both nanophotonics and nanomechanics.

Active in situ control of light at the nanoscale remains a challenge in modern physics and in nanophotonics in particular, so the researchers fabricated such an original hybrid device for the first time. Due to its electromechanical properties, graphene NEMS can be actuated and deflected electrostatically over few tens of nanometres with modest voltages applied to a gate electrode. The graphene motion can thus be used to modulate the light emission by the NVC while the emitted field can be used as a universal probe of the graphene position. The optomechanical coupling between the graphene displacement and the NVC emission is based on near-field dipole-dipole interactions.

Energy diagrams of an optical emitter and graphene

The graphene motion can thus be used to modulate the light emission by the NVC while the emitted field can be used as a universal probe of the graphene position. The optomechanical coupling between the graphene displacement and the NVC emission is based on near-field dipole-dipole interactions. The researchers could see that the coupling strength increases strongly for shorter distances and is enhanced because of graphene’s two-dimensional (2D) character and linear dispersion. These achievements hold promise for selective control of emitter arrays on-chip, optical spectroscopy of individual nano-objects, integrated optomechanical information processing, and opens new avenues toward quantum optomechanics.