Abstract
Graphene being a zero-gap material, considerable efforts have been made to develop semiconductors whose structure is compatible with its hexagonal lattice. Size reduction is a promising way to achieve this objective. The reduction of both dimensions of graphene leads to graphene quantum dots. Here, we report on a single-emitter study that directly addresses the intrinsic emission properties of graphene quantum dots. In particular, we show that they are efficient and stable single-photon emitters at room temperature and that their emission wavelength can be modified through the functionalization of their edges. Finally, the investigation of the intersystem crossing shows that the short triplet lifetime and the low crossing yield are in agreement with the high brightness of these quantum emitters. These results represent a step-forward in performing chemistry engineering for the design of quantum emitters.
Highlights
Graphene being a zero-gap material, considerable efforts have been made to develop semiconductors whose structure is compatible with its hexagonal lattice
We report on a single-emitter study that directly addresses the intrinsic emission properties of graphene quantum dots (GQDs) synthesized by this bottom–up approach
The short triplet lifetime and the low intersystem crossing (ISC) yield agree with the high brightness of these new quantum emitters
Summary
Graphene being a zero-gap material, considerable efforts have been made to develop semiconductors whose structure is compatible with its hexagonal lattice. 2 LICSEN, NIMBE, CEA, CNRS, Université Paris-Saclay, Gif sur Yvette 91191, France. We report on a single-emitter study that directly addresses the intrinsic emission properties of GQDs synthesized by this bottom–up approach.
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