Integrated Framework for MAX Phase and MXene Manufacturing, Functionalization, Multi-Modal Characterization, and Computational Modeling
This integrated approach combining advanced manufacturing, green and scalable synthesis, functionalization, structural and electrochemical characterization, and state-of-the-art computational modeling significantly advances the fundamental understanding and technological readiness of MAX phases and MXenes. Novel pilot-scale manufacturing innovations reduce hazardous reagents and dramatically shorten production times, enhancing safety and sustainability toward commercialization. Functionalization strategies and hybrid material development open new application avenues in energy storage, catalysis, biosensors, electronics, EMI shielding, additive manufacturing, and nuclear energy.
Integrated Framework of In Vitro and In Silico Toxicity Assessment
This comprehensive, multiscale assessment combining experimental in vitro toxicology, ecotoxicology, occupational exposure analysis, and advanced computational modeling significantly advances the safety evaluation of MXene nanomaterials. Used methods support the Safe and Sustainable by Design (SSbD) framework by enabling more precise hazard identification and risk prioritization. Worker exposure data inform targeted risk management enhancing occupational health during MXene production and processing. In silico approaches provide predictive tools that can reduce reliance on extensive in vitro or in vivo testing. These integrated efforts underpin the development of safer MXene materials and inform regulatory guidance and industrial best practices, thereby accelerating sustainable innovation in 2D nanomaterial technologies.