This project explores a novel Zr-Nb-Cr-Sn-Fe alloy for nuclear fuel rods, replacing Zircaloy with improved corrosion resistance and mechanical strength. The study focuses on the alloy's behavior under deep geological storage conditions, aiming to minimize hydrogen absorption.
This project aims to advance multiscale modeling of Solid Oxide Electrolysis Cells (SOEC) and Solid Oxide Fuel Cells (SOFC). The focus is to understand degradation and reliability under real operating conditions for sustainable hydrogen generation.
This project involves developing and characterizing novel liquid atomic-structured metallic surfaces for biomedical applications. The focus is on studying Ti-Zr and Mg-Ca metallic glass alloys.
This project focuses on developing an implantable, autonomous, flexible, and multifunctional blood pressure sensor for enhanced post-complex reconstructive surgery recovery. The aim is to improve patient outcomes through continuous and real-time monitoring.
This project focuses on developing alginate-based hydrogel nanocomposites loaded with metal/oxide catalysts for enhanced electro- and photo-catalytic hydrogen production. The research explores incorporating conductive, thermo-responsive, or photo-responsive polymers to improve reaction efficiency and create a multifunctional support system
This project focuses on developing innovative bioplastics from renewable resources (urban bio-waste, organic residues, biomass) using advanced techniques like electrospinning and 3D printing. The research involves incorporating bioactive molecules into biosynthesized and bio-based polymers for high-value industrial and biomedical applications, promoting a green and circular economy.
This project evaluates the techno-economic feasibility of a circular processing approach, integrating pressure-driven membrane and electrochemical technologies. The aim is to demonstrate in-situ chemical production (H2(g), NaCl(s), Na2SO4·10H2O(s)) through advanced membrane and electrochemical processes.
This project aims to create laser-patterned biomedical material surfaces with enhanced functionality, subsequently modified with bioactive peptides. The goal is to develop biocompatible materials with antibacterial properties and tissue regeneration capabilities.
This project aims to develop novel dual-property coatings for Boston Keratoprosthesis (BKPro) implants, incorporating antifibrotic and antimicrobial (antibacterial and antifungal) functionalities. The goal is to enhance long-term retention and minimize complications like retroprosthetic membrane formation and infections.
This project investigates ternary chalcogenides and kesterites for high-performance photoelectrode development, aiming to convert solar energy into sustainable chemical fuels like hydrogen using photoelectrochemical (PEC) systems. Advanced synthesis, fabrication, and characterization techniques will be employed to contribute to clean energy production and CO2 emission reduction.
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