GMMI2

This 26-hour course is teached in english and provides a structured introduction to the scientific and technological foundations of composite materials, which play a central role in aerospace, automotive, marine, energy, construction, and sports engineering. The module aims to give students a solid understanding of the historical development, fundamental concepts, classification systems, and key constituents of composite materials, along with their industrial relevance.

The course begins with a detailed historical overview of composites, starting from ancient natural reinforced materials to the emergence of high-performance composites in the 20th century driven by aeronautical and defense applications. This background highlights the technological and economic motivations behind the evolution of modern composite solutions.

The second part of the module introduces the scientific definition of a composite material as a macroscopic combination of two or more distinct constituents whose synergistic association results in superior mechanical, physical, or chemical properties compared to each component used individually.

A major section of the course is devoted to the classification of composite materials. Students learn to differentiate between:

• Polymer Matrix Composites (PMC)

• Metal Matrix Composites (MMC)

• Ceramic Matrix Composites (CMC)
  They also study the main structural families, including particulate composites, short-fiber composites, continuous fiber composites, laminates, sandwich structures, and hybrid composites. Each category is examined through its properties, performance levels, industrial applications, and processing constraints.

A substantial portion of the 26 hours focuses on the constituents of composites. The course covers reinforcing fibers — glass, carbon, aramid, basalt, and natural fibers — with emphasis on their mechanical and thermal properties, failure behaviors, and selection criteria. Matrices — thermoset polymers, thermoplastics, metals, and ceramics — are compared in terms of performance, cost, processing technologies, and durability. The fiber–matrix interface, a critical factor governing load transfer and overall composite performance, is also discussed through adhesion mechanisms, surface treatments, and coupling agents.

By combining theoretical concepts with industrial case studies and application examples, this module equips students with the essential knowledge required to understand, select, or design composite materials in an engineering context. It forms a crucial foundation for advanced courses in composite manufacturing processes, structural analysis, durability, and mechanical characterization.