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Striking analogies and dissimilarities between graphene oxides and humic acids: pH-dependent charging and colloidal stability

Etelka Tombácz, Ildikó Y. Tóth, Krisztina Kovács, Erzsébet Illés, Márta Szekeres, Balázs Károly Barna, Attila Csicsor, Tamás Szabó

2020Journal of Molecular Liquids14 citationsDOIOpen Access PDF

Abstract

This study provides a comparative framework on the elucidation of analogies and differences in the interfacial protolytic processes and the associated colloidal behaviour of a typical humic acid (HA) and a set of single-layer graphene oxide (SLGO) and (multi-layered) graphite oxide samples in aqueous electrolyte media. The pH dependence of the surface charge densities of HA and SLGO was explored at three different salt concentrations by potentiometric acid-base titration, along with simultaneous determination of zeta potential and hydrodynamic sizes. Charging curves obtained in the pH range of 3 to 10 by cyclic titrations reveal the presence of a small hysteresis, proving the chemical stability of SLGO and graphite oxides in weakly acidic and alkaline solutions. HA and SLGO display a parallel shift of the pH-dependencies of their negative charge densities with increasing ionic strength, demonstrating a unique combination of particle and polyelectrolyte-like behaviour, which is absent for multi-layered graphite oxide exhibiting charging curves that resemble to “classical” colloidal particles. An accurate purification of SLGO results in inherent change in its surface properties; however, the salt tolerance of aqueous HA solutions is still superior to that of SLGO dispersions.

Topics & Concepts

Surface chargeIonic strengthColloidTitrationPotentiometric titrationAqueous solutionZeta potentialChemistryOxideElectrolyteGraphenePolyelectrolyteGraphiteTitration curveSalt (chemistry)Inorganic chemistryAcid–base titrationHumic acidChemical engineeringIonPhysical chemistryOrganic chemistryFertilizerElectrodePolymerNanoparticleEngineeringGraphene and Nanomaterials ApplicationsGraphene research and applicationsMembrane Separation Technologies