Thesis Abstract

**Thesis Abstract
** The aerospace industry continually seeks advanced materials capable of withstanding high-temperature environments to enhance the efficiency and safety of aircraft components. This thesis focuses on the development of novel high-temperature resistant nanostructured alloys specifically designed for aerospace applications. The research aims to address the limitations of existing materials by exploring innovative alloy compositions and manufacturing techniques to improve performance at elevated temperatures. The study commences with an introduction discussing the significance of high-temperature-resistant materials in aerospace engineering. It then delves into the background of the study, highlighting the challenges faced with current alloys and the need for advanced solutions. The problem statement outlines the specific issues that this research seeks to address, emphasizing the critical importance of developing materials that can withstand extreme conditions. The objectives of the study are clearly defined to guide the research process. These objectives include the synthesis of nanostructured alloys, characterization of their properties, assessment of their high-temperature performance, and validation of their suitability for aerospace applications. The limitations and scope of the study are also outlined to provide a clear understanding of the research boundaries and focus areas. A comprehensive literature review is conducted to explore existing research on nanostructured alloys, high-temperature materials, and their applications in aerospace engineering. This review forms the basis for identifying gaps in current knowledge and guiding the development of novel alloys with enhanced properties. The research methodology section describes the experimental approach adopted for synthesizing, processing, and testing the nanostructured alloys. Various techniques such as powder metallurgy, mechanical alloying, and thermal analysis are utilized to fabricate and characterize the materials. The methodology also includes detailed procedures for evaluating the mechanical, thermal, and microstructural properties of the alloys. Chapter four presents a detailed discussion of the findings obtained from experimental testing and analysis. The results showcase the unique properties of the developed nanostructured alloys, including high-temperature stability, mechanical strength, and corrosion resistance. The implications of these findings for aerospace applications are thoroughly examined, highlighting the potential benefits of using these advanced materials in aircraft components. Finally, chapter five provides a comprehensive conclusion and summary of the thesis. The key findings, contributions, and limitations of the research are summarized, along with recommendations for future studies in this field. The significance of the developed nanostructured alloys for advancing aerospace technology is emphasized, underscoring their potential to revolutionize high-temperature applications in the aerospace industry. In conclusion, this thesis contributes to the ongoing efforts to develop innovative materials for aerospace applications by introducing novel high-temperature resistant nanostructured alloys. The research outcomes demonstrate the feasibility of enhancing material performance through advanced alloy design and processing techniques, paving the way for the next generation of high-performance aerospace materials.

Thesis Overview