Thesis Abstract

Abstract
The aerospace industry constantly seeks advanced materials with enhanced properties to improve the performance and longevity of aircraft components. This thesis investigates the corrosion resistance of novel composite materials designed for aerospace applications. The study aims to address the critical issue of corrosion in aircraft structures by exploring the potential of these advanced composites to mitigate corrosion-related damage and increase the service life of aerospace components. The research begins with a comprehensive review of existing literature on corrosion mechanisms, composite material properties, and the current state of research in the field. This literature review highlights the importance of developing corrosion-resistant materials for aerospace applications and provides a foundation for the experimental work conducted in this study. The methodology section outlines the experimental procedures and testing protocols used to evaluate the corrosion resistance of the novel composite materials. Various corrosion testing methods, including salt spray testing, electrochemical impedance spectroscopy, and scanning electron microscopy, are employed to assess the performance of the composites under different environmental conditions. The findings from the experimental work reveal promising results regarding the corrosion resistance of the novel composite materials. The composites exhibit excellent resistance to corrosion, with minimal degradation observed even after prolonged exposure to corrosive environments. The microstructural analysis of the composites provides insights into the mechanisms underlying their corrosion resistance, highlighting the role of specific additives and reinforcement materials in enhancing the protective properties of the composites. The discussion section delves into the implications of the research findings and their significance for the aerospace industry. The potential applications of these corrosion-resistant composites in aircraft design and manufacturing are explored, emphasizing the benefits of using these advanced materials to improve the durability and reliability of aerospace structures. In conclusion, this thesis contributes valuable insights into the development of corrosion-resistant composite materials for aerospace applications. The research demonstrates the feasibility of using novel composites to address the corrosion challenges faced by the aerospace industry and paves the way for further advancements in material science and engineering. The findings of this study have the potential to drive innovation in aircraft design and maintenance practices, ultimately leading to safer and more efficient aerospace systems.

Thesis Overview