posted on 2020-08-24, 19:35authored bySubhabrata Ghosh, Nazar Oleksiievets, Jörg Enderlein, Alexey I. Chizhik
Graphene
quantum dots (GQDs) are nanoparticles that consist of
a nanometer-sized core of graphene with diverse chemical groups on
its boundary. Due to their advantageous properties, they are considered
to be a promising material for optoelectronics, bioimaging, or photovoltaics.
Despite considerable efforts that have been focused on unraveling
the mechanism of their photoluminescence, many fundamental details
are still unclear. Here, we report on a single-particle multimodal
study that provides new insight into the photoluminescence properties
of emission centers of GQDs in various local chemical environments.
In particular, we show that the properties that are associated with
emission centers of GQDs are significantly more sensitive to the structure
of the particle itself than to a nonuniform local chemical environment.
A better understanding of the dependence of GQDs’ emission
states on the complex local chemical environment is an important step
toward finding new ways of controlling the optical properties of GQDs
and of optimizing their use in various applications.