Thesis Abstract

**Abstract
** The aerospace industry relies heavily on materials that can withstand extreme temperatures and environmental conditions. High-temperature resistant coatings play a crucial role in protecting aerospace components from degradation and ensuring their longevity and performance. This thesis focuses on the development of advanced coatings specifically designed for aerospace applications, with a primary goal of enhancing the durability and reliability of critical components exposed to high temperatures. The introduction sets the stage by highlighting the importance of high-temperature resistant coatings in aerospace engineering. The background of the study provides an overview of existing coatings and their limitations, emphasizing the need for innovative solutions to address the challenges faced by the industry. The problem statement identifies key issues related to the performance and longevity of coatings in high-temperature environments, directing the research towards finding viable solutions. The research objectives outline the specific goals of the study, including the development of novel coating materials, optimization of coating processes, and evaluation of coating performance under simulated aerospace conditions. The limitations of the study are acknowledged, delineating the boundaries within which the research is conducted. The scope of the study defines the parameters and extent of the research, detailing the materials, methods, and testing procedures involved. The significance of the study lies in its potential to advance the field of aerospace materials engineering by introducing new coating technologies that can withstand high temperatures and harsh operating conditions. The structure of the thesis provides a roadmap for the content and organization of the research, guiding the reader through the subsequent chapters. The literature review delves into existing research and developments in high-temperature resistant coatings, highlighting key findings, challenges, and opportunities for innovation. The research methodology outlines the experimental approach, materials selection, coating techniques, and testing procedures employed to evaluate the performance of the developed coatings. The discussion of findings presents a detailed analysis of the experimental results, including coating composition, microstructure, thermal properties, and performance characteristics. The conclusions drawn from the study summarize the key findings, contributions to the field, and implications for future research and applications in aerospace engineering. In conclusion, the development of high-temperature resistant coatings for aerospace applications represents a critical area of research with significant implications for the aerospace industry. The study contributes to the advancement of materials engineering by introducing novel coating technologies that can enhance the durability, reliability, and performance of aerospace components exposed to extreme temperatures.

Thesis Overview