Phd studentship – new approaches for studying the structure of high-temperature molten materials

PhD Studentship – New approaches for studying the structure of high-temperature molten materials

Location
UK Other

Closing Date
Friday 28 March 2025

Reference
ENG232

PhD Studentship – New approaches for studying the structure ofhigh-temperature molten materials

Transition: (October 2025 start)

Supervisor 2:Oliver Alderman(ISIS Neutron and Muon Source)

Project description: Understanding the structure and properties of high-temperature molten materials is of key importance in a diverse range of applications including optical glass manufacture, nuclear waste storage, green platforms for growth of functional materials, fuel cell hermetic seals, electrolytes, carbon capture solvents and thermal energy storage media. It is also vital for understanding natural magmatic processes on earth & other planetary bodies.

Neutron diffraction is a powerful technique for studying the atomic scale structure of these materials, but the current technology to allow measurements to be made on liquids at the high temperatures (500 o C < T < 1200 o C) required is inadequate. Current experimental setups are limited to lower temperatures and to containers that present significant problems for data reduction and analysis. This PhD project, in close collaboration with researchers at ISIS Neutron and Muon Source and University of Nottingham, will address this by designing and developing experimental equipment suitable for containing the liquids at the temperatures needed, as well as optimizing the quality of the data obtained, both through experiment design and developing the analysis techniques needed to interpret the data.

In addition to technique development, the studentship will study a range of technologically relevant high temperature liquids to provide new insights into the structure and bonding changes they undergo with temperature, upon cooling from a liquid to a glassy solid product. This will be underpinned by initial studies focussing on the structure and properties in a few compositional series of network glasses, from which key compositions to study in the molten state will be selected. Improved understanding of melt structure will have a major impact on understanding viscous flow in materials of commercial interest, such as borosilicates and boroaluminates, underpinning an array of applications from solid-oxide fuel cell seals to display glasses.

The PhD is co-funded by the Science and Technology Facilities Council (STFC) andwill be based primarily at the ISIS Neutron and Muon Source in Oxfordshire, a vibrant and world-leading international research facility operated by STFC, on behalf of the UK government and its funding partners. Visits to the University of Nottingham for training and research in the Engineering Faculty will be made as required, for example to make and characterise glasses and carryout complimentary structural measurements, with funding available to cover travel and subsistence costs. Further travel funding is available, and the student will be expected to attend training courses, and present work at both national and international conferences, with the further possibility of conducting experiments at other international research facilities, such as x-ray synchrotron light sources.

This is an exciting opportunity to work with internationally recognised experts in the fields of neutron and x-ray scattering, high-temperature and glassy materials research, to develop a wide range of skills in experimental and data analysis methodologies, and to be involved in end-to-end development and application of new, much-needed, additions to neutron diffraction sample environment capabilities.

Eligibility and Application

* Due to funding application restrictions, the position is only available for UK/eligible for home fees candidates.
* Project start date and duration: October 2025, for 3.5 years.
* Candidates must possess or expect to obtain, a 2:1 or first-class degree in Engineering, Physics, Chemistry, Materials Science, or related physical sciences discipline
* This project will include the payment of tuition fees as well as a stipend equivalent to RCUK rates
* To apply: send covering letter, CV and academic transcripts by email to Emma.Barney@nottingham.ac.uk. Applications without academic transcripts will not be considered. Please refer to the project title in your application. Applications will be evaluated on a rolling basis until a suitable candidate is appointed
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