Platinum-Based Interdigitated Micro-Electrode Arrays for Reagent-Free Detection of Copper

Water is a precious resource that is under threat from a number of pressures, including, for example, release of toxic compounds, that can have damaging effect on ecology and human health. The current methods of water quality monitoring are based on sample collection and analysis at dedicated laboratories. Recently, electrochemical-based methods have attracted a lot of attention for environmental sensing owing to their versatility, sensitivity and their ease of integration with cost effective, smart and portable readout systems. In the present work, we report on the fabrication and characterization of platinum-based interdigitated microband electrodes arrays, and their application for trace detection of copper. Using square wave voltammetry after acidification with mineral acids, a limit of detection of 0.8 mu g/L was achieved. Copper detection was also undertaken on river water samples and compared with standard analytical techniques. The possibility of controlling the pH at the surface of the sensors-thereby avoiding the necessity to add mineral acids-was investigated. By applying potentials to drive the water splitting reaction at one comb of the sensor's electrode (the protonator), it was possible to lower the pH in the vicinity of the sensing electrode. Detection of standard copper solutions down to 5 mu g/L (ppb) using this technique is reported. This reagent free method of detection opens the way for autonomous, in situ monitoring of pollutants in water bodies.

Automated summary

The study introduces a novel platinum-based microband electrode array for trace detection of copper, achieving a detection limit of 0.8 µg/L. By controlling the pH at the surface of the sensors, the detection limit for copper was lowered, allowing for detection of standard copper solutions down to 5 µg/L (ppb) without the need for reagents. This reagent-free method opens up possibilities for autonomous, in situ monitoring of pollutants in water bodies.