Description

This research centers on the fabrication and study of microfluidic devices designed for the detection of toxic metal ions. Microfluidic technology offers a promising platform for efficient and sensitive analysis of trace metal contaminants in various environmental, industrial, and biomedical applications.

The fabrication process involves utilizing advanced microfabrication techniques to create miniaturized channels and chambers within the device, enabling precise manipulation and control of fluid flows at the microscale level. The microfluidic system incorporates selective and sensitive metal ion sensors to detect the presence and concentration of toxic metal ions in real-time.

The optimization and characterization of the microfluidic devices, assessing their performance, sensitivity, and selectivity in detecting different metal ions. The research aims to achieve enhanced detection limits and rapid response times, ensuring reliable and accurate analysis of metal contaminants.

The implications of this work are far-reaching, with potential applications in environmental monitoring, industrial quality control, and medical diagnostics. The miniaturized nature of microfluidic devices allows for portability and cost-effectiveness, making them promising candidates for on-site and point-of-care metal ion detection systems. Ultimately, this research contributes to advancing the field of analytical chemistry, enabling more efficient and proactive monitoring of toxic metal pollution for a safer and healthier environment.