Application of murexide as a capping agent for fabrication of magnetite anodes for supercapacitors: experimental and first-principle studies

Abstract

In this study, we investigate the effectiveness of murexide for surface modification of Fe3O4 nanoparticles to enhance the performance of multi-walled carbon nanotube-Fe3O4 supercapacitor anodes. Our experimental results demonstrate significant improvements in electrode performance when murexide is used as a capping or dispersing agent compared to the case with no additives. When murexide is used as a capping agent, we report a capacitance of 4.2 F cm-2 from cyclic voltammetry analysis with good capacitance retention at high scan rate. From impedance measurements, we reveal a substantial decrease in the real part of impedance for samples prepared with murexide, indicating easier charge transfer at more negative electrode potentials, and reinforcing the role of murexide as a capping agent and charge transfer mediator. Density functional theory is used to investigate interactions between the murexide adsorbate and the Fe3O4 (001) surface, with a specific emphasis on adsorption strength, charge transfer, and electronic properties. This theoretical investigation uncovers a strong adsorption enthalpy of -4.5 eV, and allows us to identify the nature of chemical bonds between murexide and the surface, with significant charge transfer taking place between the Fe3O4 surface and murexide adsorbate. The transfer of electrons from the Fe3O4 surface to murexide is recognized as a vital component of the adsorption process. By examining the bonding nature of murexide on Fe3O4, this research study uncovers insights and proposes a novel bonding configuration of murexide that incorporates a combination of bridging and chelating bonding.