Module #1 Introduction to Advanced Materials Science Overview of advanced materials, their importance, and applications
Module #2 Materials Science Fundamentals Review of materials science basics, including crystal structures, bonding, and phase diagrams
Module #3 Nanomaterials Properties and applications of nanomaterials, including nanoparticles and nanotubes
Module #4 Metamaterials Design, properties, and applications of metamaterials with negative refractive index and perfect lenses
Module #5 Smart Materials Properties and applications of shape memory alloys, polymers, and gels
Module #6 Ceramic Materials Properties and applications of advanced ceramic materials, including nanoceramics and ceramic matrix composites
Module #7 Polymer Science Properties and applications of advanced polymer materials, including nanopolymers and biodegradable polymers
Module #8 Composites Properties and applications of advanced composite materials, including carbon fiber and nanocomposites
Module #9 Biomaterials Properties and applications of biomaterials, including tissue engineering and implantable devices
Module #10 Energy Storage Materials Properties and applications of advanced energy storage materials, including lithium-ion batteries and supercapacitors
Module #11 Energy Conversion Materials Properties and applications of advanced energy conversion materials, including solar cells and thermoelectric materials
Module #12 Materials for Aerospace and Defense Properties and applications of advanced materials for aerospace and defense, including high-temperature ceramics and armor materials
Module #13 Materials for Biomedical Applications Properties and applications of advanced materials for biomedical applications, including implantable devices and biosensors
Module #14 Materials for Energy Generation and Storage Properties and applications of advanced materials for energy generation and storage, including fuel cells and nuclear materials
Module #15 Materials Characterization Advanced techniques for characterizing materials, including microscopy, spectroscopy, and diffraction
Module #16 Materials Modeling and Simulation Computational modeling and simulation techniques for materials design and optimization
Module #17 Materials Synthesis and Processing Advanced techniques for synthesizing and processing materials, including 3D printing and nanofabrication
Module #18 Materials Degradation and Failure Mechanisms and analysis of materials degradation and failure, including corrosion and fatigue
Module #19 Materials for Sustainable Development Properties and applications of advanced materials for sustainable development, including green technologies and environmental remediation
Module #20 Materials for Advanced Manufacturing Properties and applications of advanced materials for advanced manufacturing, including 3D printing and nanomanufacturing
Module #21 Materials for Quantum Technologies Properties and applications of advanced materials for quantum technologies, including superconductors and topological insulators
Module #22 Materials for Soft Robotics Properties and applications of advanced materials for soft robotics, including elastomers and hydrogels
Module #23 Materials for Water Purification Properties and applications of advanced materials for water purification, including nanofiltration and membranes
Module #24 Materials for Advanced Sensors Properties and applications of advanced materials for sensors, including nanosensors and graphene-based sensors
Module #25 Course Wrap-Up & Conclusion Planning next steps in Advanced Materials Science career