Project Abstract

Abstract
The corrosion behavior of novel high-entropy alloys (HEAs) for marine applications is a critical area of research due to the increasing demand for advanced materials with enhanced corrosion resistance in harsh marine environments. This study aimed to investigate the corrosion performance of selected HEAs and compare them with traditional marine materials to assess their suitability for marine applications. The research methodology involved a series of corrosion tests, including electrochemical measurements, immersion tests, and surface analysis techniques to evaluate the corrosion resistance of HEAs under simulated marine conditions. The literature review provided a comprehensive overview of corrosion mechanisms in marine environments, the importance of material selection for marine applications, and the characteristics of HEAs that make them promising candidates for corrosion-resistant materials. The research methodology section outlined the experimental setup, sample preparation procedures, and the corrosion testing protocols employed to evaluate the corrosion behavior of HEAs. The results from the corrosion tests revealed that the selected HEAs exhibited superior corrosion resistance compared to traditional marine materials, attributed to their unique microstructural features and elemental compositions. The discussion of findings highlighted the key factors influencing the corrosion behavior of HEAs, such as alloying elements, microstructure, and environmental conditions. The comparison of corrosion performance between HEAs and conventional marine materials underscored the potential of HEAs as innovative materials for marine applications requiring high corrosion resistance. The limitations of the study, including sample size and testing duration, were acknowledged, and recommendations for future research were proposed to further explore the corrosion behavior of HEAs in diverse marine environments. In conclusion, this research contributes to the understanding of the corrosion behavior of novel high-entropy alloys for marine applications and underscores their potential as advanced materials with enhanced corrosion resistance. The significance of this study lies in the development of innovative materials that can address the challenges posed by corrosion in marine environments, leading to improved durability and longevity of marine structures and equipment. Further research in this field is essential to optimize the corrosion resistance of HEAs and facilitate their widespread adoption in marine engineering applications.

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