Fractals of graphene quantum dots in photoluminescence of shungite

TL;DR

This study investigates the fractal structures of graphene quantum dots in shungite and their influence on photoluminescence, revealing solvent-dependent fractal morphology and dual emission centers, including the first observation of spectra from individual GQDs in frozen toluene.

Contribution

It demonstrates the fractal nature of GQDs in shungite colloids and reports the first spectra of individual GQDs in frozen toluene, advancing understanding of GQD photonics.

Findings

GQDs form fractals with solvent-dependent structures.

Dual emission centers: individual GQDs and fractal structures.

First observation of GQD spectra in frozen toluene.

Abstract

Photoluminescence of graphene quantum dots (GQDs) of shungite, attributed to individual fragments of reduced graphene oxide (rGO), has been studied for the frozen rGO colloidal dispersions in water, carbon tetrachloride, and toluene. Morphological study shows a steady trend of GQDs to form fractals and a drastic change in the colloids fractal structure caused by solvent was reliably established. Spectral study reveals a dual character of emitting centers: individual GQDs are responsible for the spectra position while fractal structure of GQD colloids provides high broadening of the spectra due to structural inhomogeneity of the colloidal dispersions and a peculiar dependence on excitation wavelength. For the first time, photoluminescence spectra of individual GQDs were observed in frozen toluene dispersions which pave the way for a theoretical treatment of GQD photonics.