REVIEW ON CHARACTERIZATION OF COMPOSITE MATERIALS WITH MECHANICAL LOADING USING DIFFERENT MICROSCOPIC EXAMINATIONS FOR ENGINEERING APPLICATIONS

Abstract

Composite materials and advanced systems including ceramics, metal matrix composites, and nano-structured materials possess intricate microstructures and multifunctional characteristics. Their performance is influenced by the individual components, as well as by factors such as interfacial bonding, filler distribution and microstructural evolution during use. Precise characterization is essential for : (i) Correlate structure with properties (ii) Identify flaws or defects (iii) Predict durability and failure modes (iv) Develop next-generation high-performance materials. Due to their heterogeneous and often anisotropic nature, composite materials require highly advanced characterization techniques. Microscopy has emerged as an indispensable tool for examining microstructural features, phase distributions, fibre/matrix interfaces, defect formations and damage progression across multiple length scales. Recent advances in instrumentation and imaging methods have elevated microscopy to unprecedented levels of resolution and analytical power, providing deeper insights and improving composite performance. This chapter emphasizes the pivotal role of advanced characterization techniques in optimizing materials for structural composites, energy storage systems and semiconductor technologies. Combining scanning electron microscopy (SEM), transmission electron microscopy (TEM), X-ray diffraction (XRD) and Fourier-transform infrared spectroscopy (FTIR) greatly improves our ability to decode the complex chemical and structural properties of advanced materials. Additionally, thermos-gravimetric analysis (TGA) and differential scanning calorimetry (DSC) provide valuable information on thermal stability and how materials behave in real-world conditions. In particular, these characterization techniques have become vital for studying dynamic changes and degradation mechanisms in energy storage devices during operation. These techniques are categorized based on their primary focus: topological, structural, and compositional analysis. This chapter discusses about how advanced characterization drives the design, synthesis, and application of composite materials across diverse technological fields.

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