Functionalization of graphene sponge electrodes with two-dimensional materials for tailored electrocatalytic activity towards specific contaminants of emerging concern

Abstract

Low-cost graphene sponge electrodes were functionalized with two-dimensional (2D) materials, i.e., borophene and hexagonal boron nitride (hBN), using a one-step, hydrothermal self-assembly method. Borophene and hBN-modified graphene sponge anode and N-doped graphene sponge cathode were employed for electrochemical degradation of model persistent contaminants of emerging concern in one-pass, flow through mode, and using low-conductivity supporting electrolyte. Functionalization of the reduced graphene oxide (RGO) coating with 2D materials led to specific modifications in the electrodés electrocatalytic performance and interactions with the target contaminants. For instance, addition of hBN promoted the adsorption of more hydrophobic organic contaminants via van der Waals and π-π interactions. Functionalization of the graphene sponge anode with borophene enhanced the generation of oxidant species such as H2O2 and O3 and yielded an order of magnitude higher concentration of hydroxyl radicals (HO·) compared with the non-functionalized graphene sponge anode, thus enhancing the removal of target contaminants. Experiments conducted with the selective radical scavengers indicated the key role of surface-bound hydroxyl radicals (HO·ads) and singlet oxygen (1O2) in electrochemical degradation. The study demonstrates that functionalization of graphene sponge electrodes with 2D materials can enhance their electrocatalytic activity and modulate the interaction with specific organic contaminants, thus opening new possibilities for designing electrodes tailored to remove specific groups of pollutants.