Newcastle University, England invites online Application for number of Fully Funded PhD Degree at various Departments. We are providing a list of Fully Funded PhD Programs available at Newcastle University, England.
Eligible candidate may Apply as soon as possible.
(01) PhD Degree – Fully Funded
PhD position summary/title: PhD in Bridging Physics and Earth Observation: Geospatial foundation models for real-time flood mapping.
Flooding is one of the most significant natural hazards in the United Kingdom, with increasing frequency and severity driven by climate change and urban expansion. Accurate and timely mapping of flood extent is critical for disaster response, infrastructure resilience, and long-term planning. Traditional flood modelling approaches fall into two broad categories. Physically based hydrodynamic models, such as CityCAT, simulate flood processes with high accuracy but are computationally expensive and difficult to deploy at national scale in real time (Neal et al., 2012; Glenis et al., 2018).
In contrast, remote sensing approaches using satellite imagery, particularly from Sentinel-1, enable rapid and large-scale flood detection but are limited by issues of generalisation, dependence on labelled data, and difficulty capturing underlying hydrological processes (Schumann and Bates, 2018). Within the UK, operational flood mapping by the Environment Agency combines modelling and observations but still relies heavily on precomputed flood risk maps and does not fully exploit real-time satellite data for nationwide dynamic prediction. Recent advances in deep learning have improved performance in flood mapping tasks, yet these models often remain event-specific and struggle to transfer across geographic regions (Bentivoglio et al., 2022).
Deadline : 30th June 2026
(02) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship – Process Industries: Net Zero – Decarbonising Industrial Cellophane Production
This fully-funded PhD offers a unique opportunity to work directly with industry to decarbonise a real manufacturing plant — delivering solutions with immediate, tangible impact. This project focuses on the Futamura cellulose-to-cellophane production site in Cumbria, where you will develop strategies to reduce energy use and transition towards Net Zero operation. Unlike purely theoretical PhDs, your work will directly inform decisions in a live industrial setting.
You will be focussed on a live industrial plant, not a hypothetical system, involving direct collaboration with Futamura Ltd, a global leader in sustainable packaging, and you will deliver solutions with sector-wide relevance
This is an opportunity to be part of a Leading Research Environment, the EPSRC Centre for Doctoral Training in Process Industries: Net Zero (PINZ), hosted by the Process Intensification Group at Newcastle University. You will benefit from a cohort-based PhD experience, advanced training, and strong industry links.
Deadline : 1 July 2026
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(03) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship – Process Industries: Net Zero – Predictive Modelling of Powder Blending in Continuous Pharmaceutical Manufacturing
Are you ready to accelerate the delivery of life-saving medicines and support global Quality by Design (QbD) in pharmaceutical manufacturing?
Continuous Direct Compression (CDC) is rapidly emerging as a preferred method for pharmaceutical tablet production. A central challenge is powder blending, where active pharmaceutical ingredients (APIs) must be uniformly mixed with excipients to ensure precise, consistent dosage and product quality. Blender performance is highly sensitive to process parameters (fill level, rotation speed, blade configuration) and powder properties (particle size, shape, and surface energy). Predicting blending performance from small-scale laboratory mixers remains a major barrier to rapid CDC adoption.
In this research, you will combine particle-scale simulation with targeted experiments to develop a predictive scaling methodology linking lab-scale mixing to full CDC performance across process conditions and material properties. This work will enable faster process development, reduced material usage, and provide a quantitative foundation for predictive QbD strategies in pharmaceutical manufacturing.
This project is part of the EPSRC CDT in Process Industries: Net Zero. The successful PhD student will be co-supervised by academics from the Process Intensification Group at Newcastle University. This project is supported by Astra Zeneca, who will co-supervise the project, provide access to high power computing facilities and supply relevant data where necessary.
Deadline : 1 July 2026
(04) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship – Process Industries: Net Zero – Designing the Net‑Zero Polymer Factory: Energy Efficiency, Recovery and Novel Process Technologies
At Victrex, as an innovative world-leader in high-performance PEEK and PAEK based polymer solutions, we have a validated 1.5 °C Science Based Target to reduce operational (Scope 1 and 2) emissions by 50.4% by 2032 from a 2022 baseline. We have also committed to achieve net zero by 2050, which involves a 90% reduction in absolute emissions across our operations and value chain.
As an energy-intensive manufacturer, delivering on these targets to meet the requirements of our external stakeholders and contribute towards our customers’ decarbonisation targets, will require moving beyond sourcing renewable energy, to transformation of our processes so that our overall energy requirements are much lower, using new technologies, increasing energy efficiency and recovering waste energy.
This project will evaluate the potential opportunities to transform our use of energy and begin the transition towards net zero at our monomer and polymer manufacturing sites in the UK. This will involve:
- Reviewing currently available data and work, compile a full and detailed energy map of our processes, identifying opportunities for potential energy recovery and inefficiencies
- Modelling and optimisation of suitable energy recovery strategies
- Research into alternative innovative technologies which could deliver our chemical processes in a more efficient way (for example, alternative separation technologies)
- The potential to design “real” systems to deliver energy efficiency improvements, which could be implemented at Victrex, potentially within the project time frame
- Extrapolation of findings to other Victrex sites globally
Deadline : 1 July 2026
(05) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship – Process Industries: Net Zero – Net Zero Marine Fuels by Hydrothermal Processing of Waste
Marine transport is a difficult sector to decarbonise, as electrical power is challenging for many forms of shipping. Hence, sustainable marine fuels are required. Methanol fuel tankers are already in operation, with multiple international fleets of methanol-fuelled vessels. However, virtually all methanol is produced by steam methane reformation of natural gas, so the carbon footprint is substantial.
“Biomethanol”, derived from waste/biomass which do not compete with food production, could be the key sustainable “drop-in” marine fuel of the future. This PhD project addresses a key challenge: how to efficiently produce bio-methanol from abundant, high- moisture biomass waste feedstocks.
The research will focus on hydrothermal processing. This technology has the potential to disrupt the biofuels market by eliminating the energy-intensive drying steps typically required for wet biomass sources, thereby changing the economics. Process Intensification strategies will be employed to offer substantial advantages in energy efficiency and process economics. Various feedstocks will be examined, but a key feedstock will be digestate, a by-product of anaerobic digestion.
The project will involve collaboration with experienced engineers and scientists at Newcastle University and PuriFire as part of the PINZ (Process Industries: Net Zero) Centre for Doctoral Training in:
1. Reactor design optimisation: contribute to the design of the UK’s largest hydrothermal methanol synthesis, exploring advanced modelling techniques to maximize yield and minimize byproduct formation.
2. Scalability Studies: investigate the challenges and opportunities associated with scaling up this technology.
Deadline : 1 July 2026
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(06) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship in Computer Science in AI and Machine Learning Explainability for Different Audiences
One of the main issues with machine learning algorithms is that they are black boxes to human users. It is difficult to make sense of why a machine learning approach has provided a particular result as output. In this project, students will create explainable systems for machine learning systems. Through visualisation techniques, we will help open the black box of the model to understand training and/or predictions. This area, broadly speaking, is the target and applicants could help shape the project in this domain.
In this topic we are particularly interested in explaining machine learning methods to audiences to support explainability in these tasks where the user community is undertaking tasks outside of computer science and machine learning (for example, medicine). The focus will be on visualisation systems to support the understanding of the machine learning decisions.
Deadline : 26 June 2026
(07) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship in Medicinal Chemistry – Hydrophobic warheads to expand covalent drug discovery
The project aims to explore the potential of new warheads for the development of targeted covalent inhibitors for drug discovery. Targeted covalent inhibitors (TCIs) have vast potential to open new therapeutic avenues for undruggable targets but is currently limited by a lack of novel warheads and screening libraries. This project will involve the the design and synthesis of new covalent fragment screening libraries incorporating novel hydrophobic warheads using a Fraglite design approach (10.1021/acs.jmedchem.9b00304). This covalent fragment set will be designed for screening by both protein NMR and X-ray crystallography: the key fragment screening techniques. It will be screened against potential protein targets via both protein NMR and X-ray crystallography to identify drug discovery start points for high-value cancer targets. An iterative cycle of design-make-test will be used to optimise hit fragments identified through screening.
This is an opportunity to join a vibrant medicinal chemistry research group focussed on developing new technologies for drug discovery. It is ideally suited for a chemistry graduate looking for a career in organic or medicinal chemistry research.
The project will provide multidisciplinary training in experimental techniques across chemistry and biology, providing a highly desirable skill-set enabling research at the chemistry-biology interface.
Deadline : 8th July 2026
(08) PhD Degree – Fully Funded
PhD position summary/title: PhD studentship in microbiome and Parkinson’s Disease: A pan‑African multi‑omic and organoid investigation
Interested in how the gut microbiome contributes to Parkinson’s disease across diverse global populations?
This PhD project will explore how African diet, environment, and socioeconomic context shape Parkinson’s disease–associated gut microbiome profiles and their effects on gut biology.
Parkinson’s disease (PD) is increasing rapidly across Africa, yet most microbiome research has focused on Western populations. This PhD addresses this critical gap using one of the largest PD microbiome datasets assembled to date. You will work with a landmark pan‑African cohort of up to 2,000 adults (1,000 PD cases and 1,000 matched controls) from multiple regions, with rich clinical, dietary, environmental, and socioeconomic data. Using metagenomics and untargeted metabolomics, you will identify microbial species, pathways, and metabolites associated with PD, and determine how these vary by context.
To move beyond association, you will test mechanism using state‑of‑the‑art intestinal organoid–microbiome co‑culture models to measure the effects of bacteria on epithelial barrier integrity, inflammation, and host transcriptional responses.
The project offers interdisciplinary training in bioinformatics, advanced statistics and machine learning, anaerobic microbiology, organoid culture, and clinical interpretation of Parkinson’s disease. There may be opportunities to visit African partner sites and gain experience in global health research.
This PhD is ideal for applicants interested in microbiome science, neurodegeneration, and equitable global health research.
Deadline : 10 July 2026
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(09) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentship: Next-Generation Hair Repair Products
Human hair possesses a complex, hierarchical structure that is readily damaged during routine styling treatments involving heat, chemical processing, and mechanical stress. The global hair care market is a highly innovative and dynamic sector, estimated at more than £100 billion and growing at over 6% every year. This project aims to deliver a step-change in hair care technology by developing new strategies to form covalent bonds within hair fibres, moving beyond current approaches that rely primarily on hydrogen bonding and electrostatic interactions. While these weaker interactions can provide temporary repair, they are inherently fragile and often lost after repeated washing. Drawing inspiration from contemporary organic chemistry, this project will explore methods to permanently restore structural integrity by covalently repairing damaged bonds within hair. The project will investigate chemistries for the selective covalent modification of the hair surface, enabling durable repair and functional enhancement. A key focus will be the development of reactions that are not only effective, but also safe, non-toxic, and fully compatible with existing hair care routines. This interdisciplinary project will appeal to candidates interested in applying fundamental chemistry to real-world challenges. The student will benefit from close collaboration with scientists at Procter & Gamble Hair Care in Cincinnati.
Deadline : 30th June 2026
(10) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentships – Process Industries: Net Zero (PINZ CDT) – Theoretical and Experimental Investigation of a Microwave Plasma Device for CO2 Sequestration and Utilisation
This PhD project is part of the Process Industries: Net Zero (PINZ) Centre for Doctoral Training and will investigate the “ARCS Chamber”, a novel device for CCS and CCU. The aims of the project will be:
(i) to assess the unit’s potential for carbon sequestration from gas streams containing CO and CO₂
(ii) to develop an improved and more fundamental understanding of the mass and energy balances and reactions taking place within the system
The study will combine theoretical analysis with targeted experimental investigation to understand the physical and chemical mechanisms operating within the ARCS process. The carbon-focused part of the work will examine whether, and under what conditions, the ARCS process may support the capture, transformation, deposition, or stabilisation of carbon derived from CO and CO₂ in treated gas streams. The energy-focused part of the work will investigate the distribution of microwave energy within the system and the balance between energy input, plasma effects, gas heating and cooling, heat losses, phase changes, chemical reactions, and any other mechanisms that may explain the unexpectedly large drop in gas temperature across the chamber.
This deeper understanding will feed into the design, operation and use scenarios of the ARCS unit. This PhD is an opportunity to work on a genuinely novel, near-to-market technology and participate in its journey towards commercialisation.
Deadline : 23 June 2026
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(11) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentships – Process Industries: Net Zero – Development of a Novel Microwave Non-thermal plasma Reactor for Carbon Dioxide Capture and Utilisation
This PhD project is part of the Process Industries: Net Zero (PINZ) Centre for Doctoral Training and will focus on developing the design of a novel microwave-based non-thermal reactor developed by ARCS Evolution Ltd. The reactor is known as the “ARCS chamber” and is used for non-thermal plasma treatment of gas streams. The aim of the PhD is to understand how chamber design and operating conditions influence exhaust gas clean-up performance. The study will focus on the interaction between chamber geometry, chamber construction materials, microwave operating conditions, and gas-stream properties, and how variation in these factors affects the removal or conversion of key gas-phase species and particulate content.
A structured Design of Experiments (DOE) methodology will be used to investigate the principal operating variables to be explored, allowing rapid exploration of the parameter space. The research will combine design space exploration, heuristic investigation, and statistical analysis to identify promising chamber configurations and operating windows. The outcome will be a clearer engineering understanding of how ARCS chamber design can be varied to improve the performance of non-thermal plasma treatment for polluted gas streams.
Deadline : 23 June 2026
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(12) PhD Degree – Fully Funded
PhD position summary/title: PhD Studentships – Process Industries: Net Zero Centre for Doctoral Training – Chemical Engineering for Sustainable Wastewater-to-Resource Systems
This PhD project targets a key challenge in sustainable process engineering: translating microbial electrolysis cell (MEC) technology from lab-scale innovation to robust, industrial deployment.
The research will sit at the interface of reaction engineering, process systems engineering, and industrial deployment.
You will develop and optimise scalable MEC systems for real industrial wastewater, focusing on process intensification, dynamic operation, and resource recovery. The project combines modelling, pilot-scale experimentation, and techno-economic assessment to establish MECs as viable unit operations within next-generation wastewater treatment plants.
You will contribute to technology being developed for real-world deployment with water utilities and food & beverage manufacturers, working closely with the spinout company METzero Technologies.
Deadline : 23 June 2026
About Newcastle University, England –Official Website
Newcastle University (legally the University of Newcastle upon Tyne) is a public research university based in Newcastle upon Tyne, North East England. It has overseas campuses in Singapore and Malaysia. The university is a red brick university and a member of the Russell Group, an association of research-intensive UK universities.
The university finds its roots in the School of Medicine and Surgery (later the College of Medicine), established in 1834, and the College of Physical Science (later renamed Armstrong College), founded in 1871. These two colleges came to form the larger division of the federal University of Durham, with the Durham Colleges forming the other. The Newcastle colleges merged to form King’s College in 1937. In 1963, following an Act of Parliament, King’s College became the University of Newcastle upon Tyne.
The university subdivides into three faculties: the Faculty of Humanities and Social Sciences; the Faculty of Medical Sciences; and the Faculty of Science, Agriculture and Engineering. The university offers around 175 full-time undergraduate degree programmes in a wide range of subject areas spanning arts, sciences, engineering and medicine, together with approximately 340 postgraduate taught and research programmes across a range of disciplines.The annual income of the institution for 2021–22 was £543.2 million of which £109.6 million was from research grants and contracts, with an expenditure of £624.3 million.
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