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Composite materials have played a transformative role in human technological development, from ancient straw-reinforced clay bricks to advanced carbon fiber-reinforced polymers used in aerospace and biomedical engineering. This thesis examines the historical evolution of composite materials, analyzes key scientific and technological breakthroughs, and explores future trends including nanocomposites, smart materials, sustainable composites, and additive manufacturing applications. The study applies a qualitative literature review methodology combined with comparative technological analysis. Findings demonstrate that composite materials have consistently driven innovation by offering superior strength-to-weight ratios, corrosion resistance, durability, and multifunctionality. Future development is expected to focus on sustainability, recyclability, integration of artificial intelligence in material design, and bio-inspired composite structures. The research confirms that composite materials will remain central to aerospace, automotive, construction, renewable energy, and medical industries.
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