Thesis Abstract

Abstract
This thesis investigates the effects of grain size on the mechanical properties of titanium alloys. The study aims to contribute to the understanding of how variations in grain size affect the mechanical behavior of titanium alloys, which are widely used in aerospace, automotive, and medical industries due to their excellent combination of high strength, low density, and corrosion resistance. The research methodology involved the fabrication of titanium alloy samples with controlled grain sizes through different heat treatment processes, followed by a comprehensive characterization of their microstructure and mechanical properties. The literature review in Chapter Two provides a detailed analysis of previous studies on the relationship between grain size and mechanical properties in various metal alloys, highlighting the importance of grain size control in optimizing material performance. Chapter Three outlines the research methodology, including sample preparation, heat treatment procedures, mechanical testing techniques, and microstructural analysis methods. The experimental results presented in Chapter Four demonstrate the influence of grain size on tensile strength, hardness, ductility, and fracture toughness of titanium alloys. The discussion of findings in Chapter Four interprets the experimental data and discusses the underlying mechanisms governing the observed trends in mechanical properties with varying grain sizes. Factors such as grain boundary strengthening, dislocation movement, and deformation mechanisms are analyzed to elucidate the complex relationship between grain size and mechanical behavior in titanium alloys. The significance of the study lies in its potential to guide the development of grain size optimization strategies for enhancing the mechanical performance of titanium alloys in different engineering applications. In conclusion, this research provides valuable insights into the effects of grain size on the mechanical properties of titanium alloys, contributing to the advancement of materials science and engineering knowledge. The findings offer practical implications for the design and manufacturing of titanium components with tailored mechanical properties for specific industrial requirements. Future research directions could focus on further investigating the microstructural evolution and mechanical response of titanium alloys under different processing conditions to expand the understanding of grain size effects on material behavior.

Thesis Overview