Technical Summary

The primary focus of Joseph’s research is on compositional control for controlled PBF-LB of NiTi-alloys, aiming to enhance their microstructure and part properties. The technical challenge lies in achieving precise control over the composition and microstructural characteristics of NiTi-alloys to improve their functional performance in industrial applications, such as actuators and other phase-changing devices.

This research is significant because it addresses the critical need for advanced materials that can offer superior performance and reliability in demanding applications. By investigating the effects of copper addition, Joseph’s work seeks to optimise the additive manufacturing parameters to produce NiTi-alloys with enhanced properties. This involves exploring the thermal characteristics, mechanical characteristics, and actuation response.

The novelty of Joseph’s research lies in the integration of copper into NiTi-alloys and the subsequent analysis of its effects on material properties. This approach provides a new understanding of how compositional changes can influence the performance of advanced materials, paving the way for innovative applications.

The excitement in his research stems from its potential to revolutionise the manufacturing of high-performance materials. By developing new compositions and refining process parameters, Joseph’s work contributes to the advancement of additive manufacturing technologies. This has broader implications for the manufacturing industry, enhancing the efficiency, adaptability, and sustainability of production processes. Ultimately, his research aims to push the boundaries of materials science and engineering, fostering innovation and practical applications in fields ranging from aerospace to biomedical engineering.