Category: Research

Our project focuses on microplastic detection and degradation, addressing a critical environmental challenge. We’re committed to developing advanced methods for detecting and breaking down these harmful particles. Together, we’re working towards a cleaner and healthier planet. Collaborator: Dr. Mainul HossainAssistant ProfessorDepartment of Electrical and Electronic EngineeringFaculty of Engineering and TechnologyEmail:

Our project explores the exciting world of nano-enabled agriculture. In Bangladesh, we’re studying how nano-priming can enhance soil health, plant growth, and crop yield. Our research goes beyond short-term effects, focusing on long-term sustainability. Plus, we’re fine-tuning nanoparticle sizes for optimal results and exploring exciting combinations with traditional treatments. Stay

The properties of core-shell plasmonic nanoparticles, including scattering, extinction, absorption, and thickness, are heavily influenced by their fabrication materials. Our work involves an AI-driven approach to streamline the selection of these nanoparticles. Using neural networks, the study aims to predict the best core-shell combinations based on specific desired parameters. This

Split-ring resonator-based sensors are well known for being sensitive to changes in the dielectric constant of their surrounding which gives rise to their potential to be used as low-cost sensors for various applications. In our work, we plan to test split ring resonator-based sensors to be used in biosensing applications

This project focuses on the development of a groundbreaking Flexible, Stretchable, and Single-molecule-sensitive SERS-active sensor. This innovative sensor utilizes gold nanoparticles on a polydimethylsiloxane (PDMS) substrate to achieve flexibility, stability, transparency, and biocompatibility. The sensor demonstrates an exceptional SERS Enhancement Factor of approximately 10^11, surpassing previous limits, while maintaining a