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- Tasks: Develop a theoretical framework for neutron-nucleus interactions using machine learning and probabilistic methods.
- Company: Join a leading research team in nuclear science with global collaborations.
- Benefits: Fully funded PhD, competitive stipend, and opportunities for international research visits.
- Why this job: Make groundbreaking contributions to nuclear science while gaining skills in data science and AI.
- Qualifications: Open to candidates with a strong background in nuclear data and statistical modelling.
- Other info: Collaborate with top researchers and gain exposure to large-scale scientific projects.
The predicted salary is between 18000 - 24000 £ per year.
Neutron-nucleus cross sections can be divided into different energy ranges depending on the initial energy of the neutron. At lower energies, cross sections are characterised by peaks, called resonances, caused by the neutron being absorbed by the target nucleus. Positions and widths of these resonances cannot be predicted and must be measured. This energy range is called the “resolved resonance region” (RRR). Increasing further the energy of the neutron we reach a point where the resonances in the cross section are too close to each other to be resolved experimentally and we can only infer the average values of the widths and spacings between two adjacent resonances. This energy range is called the “unresolved resonance region” (URR).
Current computational methods treat the resonances in the URR using delta functions in place of full conditional cross section probability distributions to represent the probability of individual reaction channels (capture, elastic, fission), potentially missing more complex correlations between the channels. Moreover, this method does not allow to easily include information from different sources, for example from nuclear experiments. Additionally, for many applications we also need to know the cross sections at different temperatures and, thus, we need to properly account for the thermal motion of the target nuclei.
Due to these issues, we need to develop a theoretical framework that allows us to consistently treat the URR, the available experimental information, and the target thermal motion of the cross sections of neutron-induced reactions relevant for nuclear science and applications. This project aims to develop the required formalism using modern probabilistic and machine-learning approaches, reformulating the problem in terms of conditional probabilities. Bayesian networks and related machine-learning methods will be used to calculate cross-section probability density functions in a much faster way, enabling the combination of multiple probability distributions describing various physical effects.
Supervisors: Dr Matteo Vorabbi, Prof Paul Stevenson and James Benstead
Entry requirements: Open to candidates who pay UK/home rate fees. See UKCISA for further information. Starting in October 2026. You will need to meet the minimum entry requirements for our PhD programme.
This project will allow the student to acquire highly transferable skills in probabilistic modelling, statistical inference, and machine-learning techniques, with potential applications well beyond nuclear science, including data science and AI-related fields. Expertise in nuclear data and uncertainty quantification is highly desirable, making the student a strong candidate for both academic and applied research environments following completion of the project.
The PhD student is also expected to collaborate closely with a number of UK and international partners, including opportunities for visits to the US national laboratories of Brookhaven and Lawrence Livermore, providing exposure to large-scale scientific projects and interdisciplinary research environments.
How to apply: The application should be submitted via the Physics PhD programme page as a single PDF file containing CV, personal statement (one page maximum) and contacts for two references. Please clearly state the studentship title and supervisor on your application.
Funding: Fully and directly funded for this project only, including UKRI standard stipend; funding is for 4 years; funded by AWE Nuclear Security Technologies.
Application deadline: 31 March 2026
Enquiries: Contact Dr Matteo Vorabbi Ref PGR-2526-021
PhD Studentship: A new theoretical framework for the unresolved resonance region in Guildford employer: University of Surrey
Contact Detail:
University of Surrey Recruiting Team
StudySmarter Expert Advice 🤫
We think this is how you could land PhD Studentship: A new theoretical framework for the unresolved resonance region in Guildford
✨Tip Number 1
Network like a pro! Reach out to your professors, colleagues, and even alumni who might have connections in the nuclear science field. A friendly chat can lead to opportunities you wouldn't find on job boards.
✨Tip Number 2
Prepare for interviews by diving deep into the specifics of the unresolved resonance region. Brush up on your knowledge about neutron-nucleus interactions and be ready to discuss how your skills in probabilistic modelling and machine learning can contribute to the project.
✨Tip Number 3
Showcase your passion! When you get the chance to speak with potential supervisors or during interviews, let them know why this PhD studentship excites you. Your enthusiasm can set you apart from other candidates.
✨Tip Number 4
Don’t forget to apply through our website! Make sure your application is polished and includes all required documents. A well-organised submission can make a great first impression.
We think you need these skills to ace PhD Studentship: A new theoretical framework for the unresolved resonance region in Guildford
Some tips for your application 🫡
Craft a Stellar CV: Your CV is your first impression, so make it count! Highlight your relevant experience, skills in probabilistic modelling, and any machine-learning projects you've tackled. Tailor it to show how you fit into the exciting world of nuclear science.
Nail Your Personal Statement: Keep it concise and focused—one page max! Use this space to express your passion for the subject and why you're the perfect fit for this PhD. Mention your interest in collaborating with international partners and how you plan to contribute to the project.
Reference Matters: Choose your referees wisely! Pick two people who can vouch for your academic prowess and research potential. Make sure they know what the studentship entails so they can tailor their references to highlight your suitability.
Submit Through Our Website: Don't forget to apply via the Physics PhD programme page! Ensure all your documents are in a single PDF file and clearly state the studentship title and supervisor. We can't wait to see your application!
How to prepare for a job interview at University of Surrey
✨Know Your Stuff
Make sure you have a solid understanding of neutron-nucleus interactions and the unresolved resonance region. Brush up on key concepts like cross sections, resonances, and Bayesian networks. Being able to discuss these topics confidently will show your passion and expertise.
✨Showcase Your Skills
Highlight any experience you have with probabilistic modelling, statistical inference, or machine-learning techniques. Be ready to share specific examples of how you've applied these skills in past projects or research. This will demonstrate your readiness for the challenges of the PhD.
✨Ask Smart Questions
Prepare thoughtful questions about the project and the supervisors' research interests. This not only shows your enthusiasm but also helps you gauge if the environment is the right fit for you. Think about how you can contribute to their ongoing work.
✨Be Yourself
While it's important to be professional, don't forget to let your personality shine through. The interviewers want to see if you'll fit into their team. Share your motivations for pursuing this PhD and how it aligns with your career goals.
