Abstract
It is imperative to utilize nanotechnology in body-integrated sensors and fuel cell technologies. In accordance with these two purposes, this study focused on developing a suitable nanocatalyst structure to contribute to both glucose sensors and direct glucose fuel cell research. We primarily produced carbon nanofiber (CNF) structures using the electrospinning method. Carbon nanofiber-supported bimetallic palladium/nickel nanoalloy (PdNi@CNF) with high electrocatalytic activity was produced by the chemical reduction method to replace platinum-based nanostructures. CNF-supported PdNi structures were revealed by scanning electron microscope (SEM), and the average fiber diameter was calculated as 35.86 nm. In this study, this PdNi@CNF nanostructure was produced as an electrocatalyst for non-enzymatic glucose sensing (NEGS) and direct glucose fuel cell (DGFC) applications. It was modified by the drop-casting method on a glassy carbon electrode (GCE). The (Limit of Detection) LOD value for the PdNi@CNF structure was 5.93 mM, and the (Limit of Quantification) LOQ value was 17.95 mM. The PdNi@CNF electrode exhibits a low detection limit, high selectivity, short response time for NEGS, long-term stability, and high current value for DGFC applications. Briefly, an ideal catalyst that can operate in low alkaline environments and that can be used in NEGS and DGFC structures has been synthesized in this work. The results have shown that it can be used as a body-integrated sensor structure and a long-term stable catalyst in future studies.