[Fully funded studentships, including a minimum tax-free stipend, are available for home fee-eligible students. International students may be considered if exceptionally qualified.] The University of Nottingham’s Centre for Additive Manufacturing (CfAM) Research Group, part of the Faculty of Engineering, is offering a fully funded PhD studentship focused on advanced multi-metal additive manufacturing for future energy and technology systems. CfAM is internationally recognised for its pioneering research in additive manufacturing, providing an outstanding environment for doctoral research and professional development. This PhD project centres on Molten Metal Jetting (MMJ), a cutting-edge metal 3D printing technology that enables the precise fabrication of multi-material metallic structures. MMJ offers significant advantages, including reduced material waste and minimal post-processing, and CfAM has developed a unique platform capable of printing two metals within a single build at microscopic resolution. The research aims to extend MMJ technology to high-melting-point metals and alloys, which are essential for demanding engineering applications in clean energy, electronics, and advanced technologies. The successful candidate will contribute to the design, modelling, and development of a high-temperature crucible and droplet ejection system, ensuring reliable operation under severe thermal and chemical conditions. The project will combine computational modelling, system design, and experimental testing to optimise the printing process. A key aspect will be the fabrication and characterisation of 3D multi-material metal structures, with a focus on understanding interactions between dissimilar materials at the microscale. Research will be conducted within a multidisciplinary team of academics, postdoctoral researchers, and technical staff, leveraging CfAM’s world-class facilities. The project is both industrially relevant and scientifically significant, offering opportunities to collaborate with industrial partners, develop skills across multiple disciplines, and present research at national and international conferences. Eligibility: Applicants should hold a first or upper second-class degree in Engineering, Physical Sciences, or a related discipline. Experience with coding (e.g., MATLAB or LabVIEW) and familiarity with multiphysics simulation tools are beneficial. Creative thinking, independence, and industry experience are valued. International students may apply, but only exceptional candidates (such as those with first-author publications) will be considered due to funding limitations. Funding: The studentship is fully funded for home fee-eligible students, including a minimum tax-free stipend. International students may be considered if exceptionally qualified. Application Process: Applications should include a covering letter, CV, and academic transcripts, sent to [email protected]. Applications without transcripts will not be considered. The deadline for applications is 18 March 2026, but early applications are encouraged as evaluation is on a rolling basis until a suitable candidate is appointed. The University of Nottingham is committed to diversity and inclusion, and the Faculty of Engineering holds an Athena SWAN Gold Award for its support of women’s careers in engineering.

The Centre for Additive Manufacturing (CfAM) at the University of Nottingham is seeking a PhD candidate to join a pioneering project in multi-material molten metal jetting, a next-generation metal additive manufacturing technology. This research sits at the intersection of materials science, manufacturing, and design, focusing on the development and optimization of advanced metal 3D printing processes. The project aims to extend molten metal jetting (MMJ) technology to high-melting-point metals and alloys, enabling the fabrication of complex, multi-material metallic structures with applications in clean energy, electronics, and advanced engineering systems. The successful candidate will work within a multidisciplinary team, contributing to the design, computational modelling, and experimental development of high-temperature crucible and droplet ejection systems. The research will involve system design, fabrication, and microscale characterization of 3D metal structures, with a strong emphasis on understanding material interactions at the microscale. The project offers opportunities to engage with industrial partners and present research at national and international conferences, leveraging the world-class facilities at CfAM. Eligibility requirements include a first or upper second-class degree in Engineering, Physical Sciences, or a related field. Experience with coding (such as MATLAB or LabVIEW) and familiarity with multiphysics simulation tools are advantageous. Creative thinking, independence, and industry experience are valued. The studentship is fully funded for home students, covering tuition and a tax-free stipend. Outstanding international candidates may be considered for alternative funding. Applications are reviewed on a rolling basis, and early submission is encouraged. To apply, send a covering letter, CV, and academic transcripts to Dr. Negar Gilani at [email protected]. The University of Nottingham is committed to diversity and inclusion, with the Faculty of Engineering recognized for advancing women’s careers in engineering. This is an excellent opportunity for candidates interested in additive manufacturing, materials science, and advanced engineering research.

[Fully funded studentships, including a minimum tax-free stipend, are available for home fee-eligible students. International students may be considered if exceptionally qualified.] The University of Nottingham’s Centre for Additive Manufacturing (CfAM) Research Group, part of the Faculty of Engineering, is offering a fully funded PhD studentship focused on advanced multi-metal additive manufacturing for future energy and technology systems. CfAM is internationally recognised for its pioneering research in additive manufacturing, providing an outstanding environment for doctoral research and professional development. This PhD project centres on Molten Metal Jetting (MMJ), a cutting-edge metal 3D printing technology that enables the precise fabrication of multi-material metallic structures. MMJ offers significant advantages, including reduced material waste and minimal post-processing, and is highly relevant for applications in clean energy, electronics, and advanced engineering technologies. CfAM has developed a unique multi-material MMJ platform capable of printing two metals within a single build at microscopic resolution, opening new possibilities for complex component design. The successful candidate will work on extending MMJ technology to high-melting-point metals and alloys, which are essential for demanding engineering applications. The research will involve designing, modelling, and developing a high-temperature crucible and droplet ejection system, ensuring reliable operation under severe thermal and chemical conditions. The project combines computational modelling, system design, and experimental testing to optimise the printing process and will include the fabrication and characterisation of 3D multi-material metal structures, with a focus on understanding microscale interactions between dissimilar materials. As part of a multidisciplinary team, the student will collaborate with academics, postdoctoral researchers, and technical staff, utilising CfAM’s world-class facilities. The project is both industrially relevant and scientifically significant, offering opportunities to engage with industrial partners, develop skills across multiple disciplines, and present research at national and international conferences. Eligibility requirements include a first or upper second-class degree in Engineering, Physical Sciences, or a related discipline. Experience with coding (MATLAB or LabVIEW) and multiphysics simulation tools is desirable, as is evidence of creative thinking and independent work. Industry experience is advantageous. The studentship is fully funded for home fee-eligible students, including a minimum tax-free stipend. International students may apply, but only exceptional candidates (e.g., those with first-author publications) will be considered due to funding restrictions. Applications should include a covering letter, CV, and academic transcripts, and be sent to Dr Negar Gilani at [email protected]. Applications without transcripts will not be considered. The University of Nottingham is committed to diversity and inclusion, and encourages applications from all backgrounds. The Faculty of Engineering holds an Athena SWAN Gold Award for its support of women’s careers in engineering. The application deadline is 18 March 2026, but applications will be reviewed on a rolling basis until the position is filled. Early applications are strongly encouraged. For further details and to apply, visit https://jobs.nottingham.ac.uk/ENG296 .

[Fully funded studentships including a minimum tax-free stipend are available for home fee-eligible students. International students may be considered if exceptionally qualified.] The University of Nottingham’s Centre for Additive Manufacturing (CfAM), a world-leading research group within the Faculty of Engineering, is offering a fully funded PhD studentship focused on advanced multi-metal additive manufacturing for future energy and technology systems. This opportunity is supervised by Dr Negar Gilani and Professor Richard Hague, both prominent figures in the field. The CfAM has pioneered the development of a unique multi-material Molten Metal Jetting (MMJ) platform, capable of printing two metals within a single build at microscopic resolution. This technology is revolutionising the fabrication of complex metallic structures, reducing material waste and minimising post-processing requirements. The PhD project will advance MMJ technology to accommodate high-melting-point metals and alloys, essential for demanding engineering applications. The research will involve designing, modelling, and developing a high-temperature crucible and droplet ejection system, ensuring reliable operation under severe thermal and chemical conditions. Candidates will engage in computational modelling, system design, and experimental testing to optimise the printing process. Additionally, the project includes the fabrication and characterisation of 3D multi-material metal structures, with a particular focus on understanding microscale interactions between dissimilar materials. This research is conducted within a multidisciplinary team, including academics, postdoctoral researchers, and technical staff, utilising CfAM’s world-class facilities. The project is both industrially relevant and scientifically significant, offering opportunities to collaborate with industrial partners, develop skills across multiple disciplines, and present research at national and international conferences. Applicants should possess a first or upper second-class academic qualification in engineering, physical sciences, or a related discipline. Experience with coding (such as MATLAB or LabVIEW) and familiarity with multiphysics simulation tools are advantageous. Creative thinking, independence, and industry experience are valued. Fully funded studentships, including a minimum tax-free stipend, are available for home fee-eligible students. International applicants are welcome, but only exceptional candidates (e.g., those with first-author publications) will be considered due to funding restrictions. To apply, email your covering letter, CV, and academic transcripts to Dr Negar Gilani at [email protected]. Applications without academic transcripts will not be considered. The deadline for applications is 10 August 2026, but early applications are encouraged as evaluation is on a rolling basis. The University of Nottingham is committed to diversity and inclusion, and the Faculty of Engineering holds an Athena SWAN Gold Award for advancing women’s careers in engineering. For further information, visit the project webpage: https://www.nottingham.ac.uk/engineering/pg-research/phd-projects/multi-metal-additive-manufacturing.aspx .