Performance-Enhanced Non-Enzymatic Glucose Sensor Based on Graphene-Heterostructure
Mahmoud A. Sakr, Karim Elgammal, Anna Delin, Mohamed Serry

TL;DR
This paper introduces a graphene-based heterostructure glucose sensor with enhanced sensitivity and selectivity, achieved by optimizing platinum oxide layer thickness and supported by theoretical DFT analysis, promising improvements for continuous glucose monitoring.
Contribution
The study presents a novel G/PtO/n-Si heterostructure sensor with significantly improved sensitivity through layer optimization and theoretical insights into its detection mechanism.
Findings
Sensitivity increased by 150% with thicker PtO layers.
Achieved detection of 4-10 mM glucose with high selectivity.
Theoretical DFT analysis explained charge distribution and selectivity.
Abstract
This study proposes a novel design of glucose sensor with enhanced selectivity and sensitivity by using graphene Schottky diodes, which is composed of Graphene (G)/Platinum Oxide (PtO)/n-Silicon (Si) heterostructure. The sensor was tested with different glucose concentrations and interfering solutions to investigate its sensitivity and selectivity. Different structures of the device were studied by adjusting the platinum oxide film thickness to investigate its catalytic activity. It was found that the film thickness plays a significant role in the efficiency of glucose oxidation and hence in overall device sensitivity. 0.8-2 uA output current was obtained in the case of 4-10 mM with a sensitivity of 0.2 uA/mM.cm2. Besides, results have shown that 0.8 uA and 15 uA were obtained by testing 4 mM glucose on two different PtO thicknesses, 30 nm, and 50 nm, respectively. The sensitivity of…
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