Abstract
Electron Paramagnetic Resonance (EPR) is a powerful technique that is suitable to study graphene-related materials. The challenging ability requested to the spectroscopy is its capability to resolve the variety of structures, relatively similar, that are obtained in materials produced through different methods, but that also coexist inside a single sample. In general, because of the intrinsic inhomogeneity of the samples, the EPR spectra are therefore a superposition of spectra coming from different structures. We show that by pulse EPR techniques (echo-detected EPR, ESEEM and Mims ENDOR) we can identify and characterize species with slow spin relaxing properties. These species are generally called molecular states, and are likely small pieces of graphenic structures of limited dimensions, thus conveniently described by a molecular approach. We have studied commercial reduced graphene oxide and chemically exfoliated graphite, which are characterized by different EPR spectra. Hyperfine spectroscopies enabled us to characterize the molecular components of the different materials, especially in terms of the interaction of the unpaired electrons with protons (number of protons and hyperfine coupling constants). We also obtained useful precious information about extent of delocalization of the molecular states.
Highlights
Graphene is nowadays one of the materials that is driving recent technological developments, with applications in different areas, like energetics [1], electronics [2], medicine and bioimaging [3,4], catalysis [5] and many more
We have studied commercial reduced graphene oxide and chemically exfoliated graphite, which are characterized by different Electron Paramagnetic Resonance (EPR) spectra
In this study we have considered two types of samples: reduced graphene oxide (RGO), as a standard material extensively studied, and graphene obtained by exfoliation of graphite with different chemical procedures
Summary
Graphene is nowadays one of the materials that is driving recent technological developments, with applications in different areas, like energetics [1], electronics [2], medicine and bioimaging [3,4], catalysis [5] and many more. Besides the first method of production of graphene, based on the simple scotch-tape technique [7], a bunch of methodologies have been developed; chemical vapour deposition (CVD), reduction of graphene oxide (GO) obtained by the Hummers method [8] and exfoliation of graphite [9] are the most popular. Materials produced with these methods have a variety of properties which derive from the structural modifications, the eventual stacking of layers, the dimensionality [10] and the presence of defects [11]. Most common techniques used for characterization of these materials are Raman spectroscopy [12], XRD [13] and microscopies (AFM, SEM, TEM) [14] which are used in particular to study properties like structure, number of stacked graphene layers, crystallinity, presence of defects, dimension of crystallites
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