PhD projects for 2026

The University of Reading is a world leader in climate science, and winner of the Queen’s Anniversary Prize.

We have won numerous accolades for our climate and sustainability work, including:

• Sustainable University of the Year, The Times and Sunday Times Good University Guide, 2025
• 1st in the People & Planet University League 2023/24, and 4th in 2024/25
• Winner of Outstanding Contribution to Sustainability Leadership, London Higher Award 2024
• First ever winner of the Times Higher Education Outstanding Contribution to Environmental Leadership award, 2023.

Our School of Mathematical, Physical and Computational Science was also awarded the Athena Swan Silver Award in 2023, in recognition of good employment practices related to women working in science, engineering and technology.

Information on how to apply for any of these projects can be found on the Mathematics for our Future Climate page.

Currently, climate reconstructions over the last century have large uncertainties. This is because the algorithms used to assimilate observations with models only take observations prior to the times of interest, as they were designed for numerical weather prediction. Using rapidly developing machine learning algorithms, you will explore ways of projecting observations backwards in time to improve the full temporal consistency, leading to better understanding of change.

Supervisors

• Keith Haines (University of Reading and National Centre for Earth Observation)
• Yumeng Chen (University of Reading and National Centre for Earth Observation)
• Daniel Lea (Met Office, UK).

Partner

Met Office, UK.

Rare and extreme events are getting more common and causing severe consequences due to climate change. This PhD project is aimed at developing advanced statistical sampling and multiscale computer simulation methods to investigate rare events and their transition dynamics in complex systems related to weather, climate and environmental sustainability.

Supervisors

• Zuowei Wang (University of Reading)
• Jeroen Wouters (University of Reading)
• Richard Everitt (University of Warwick)

The production of food strongly depends on a small number of global “breadbaskets”. This poses a significant risk should several of them fail at the same time. We will develop and apply novel statistical and computational methods to assess how climate change affects these risks.

Supervisors

• Jeroen Wouters (University of Reading)
• Abhishek Pal Majumder (University of Reading)
• Valerio Lucarini (University of Leicester)

Join an exciting PhD project tackling the urgent challenge of verifying climate change. You’ll develop innovative distributed inference methods for extreme climate events, aggregating extreme value index estimates from diverse, spatially distributed data – even with missing values – to create robust statistical tools that drive impactful climate analysis.

Supervisors

• Abhishek Pal Majumder (University of Reading)
• Jeroen Wouters (University of Reading)
• Claudia Neves (King’s College)

Join the drive to revolutionise weather forecasting. This project combines cutting-edge AI, high-resolution simulations, and crowd-sourced observations to tackle the challenge of predicting extreme storms and localised weather. Innovative methods will assess accuracy, realism and uncertainty, advancing science that protects lives and communities.

Supervisors

• Helen Dacre (University of Reading)
• Jochen Broecker (University of Reading)
• Lewis Blunn (Met Office, UK)
• Sylvia Bohnenstengel (Met Office, UK)

Partner

Met Office, UK

As extreme weather events become more frequent in our changing climate, weather forecast accuracy is crucial for saving lives and livelihoods. This project will explore innovative methods to enhance next-generation weather prediction using high resolution satellite data, drawing on techniques at the intersection of numerical linear algebra and machine learning.

Supervisors

• Sarah Dance (University of Reading and National Centre for Earth Observation)
• Alison Fowler (University of Reading and National Centre for Earth Observation)
• Rishabh Bhatt (University of Reading and National Centre for Earth Observation)

Partner

National Centre for Earth Observation

Mesoscale eddies (ocean currents flowing in closed patterns) are essential players in the Earth's climate, but existing climate models are unable to accurately simulate their effects. In this project, we will contribute to the development of parameterisations of eddy transport across continental margins, where large variations in ocean depth exist.

Supervisors

• David Ferreira (University of Reading)
• André Palóczy (National Oceanography Centre)

Partner

National Oceanography Centre

How is climate change impacting life on Earth? We will use unique historical data on wild birds from a biodiversity hotspot, Madagascar, to investigate this. Our project will combine museum specimens and modern data to explore how climate and land-use change are reshaping the ranges of Madagascar birds through time.

Supervisors

• Deepa Senapathi (University of Reading)
• Emily Black (University of Reading)
• Ken Norris (Natural History Museum)
• Arianna Salili-James (Natural History Museum)

Partner

Natural History Museum

This project will develop a novel, data-driven machine-learning-based modelling framework to provide near-real time predictions of the distributions of the highly mobile Celtic Sea cod, which is sought after by UK and EU fisheries managers and policy makers, as well as by the International Council for Exploration of the Seas.

Supervisors

• Shovonlal Roy (University of Reading)
• Robert Thorpe (Centre for Environment, Fisheries and Aquaculture Science)
• Paul Dolder (Centre for Environment, Fisheries and Aquaculture Science)
• Hong Wei (University of Reading)

Partner

Centre for Environment, Fisheries and Aquaculture Science (CEFAS)

Predicting potential tipping points in the Atlantic Meridional Overturning Circulation (AMOC) is an exciting application of stochastic differential equation (SDE) modeling. This PhD project aims to analyze SDE models using simulated climate data, explore the sensitivity of predictions to noise, and refine early warning indicators for potential abrupt circulation changes.

Supervisors

• Abhishek Pal Majumder (University of Reading)
• Jeroen Wouters (University of Reading)
• Jon Robson (University of Reading)

Extreme events, such as droughts, can have devastating impacts. However, both the limited observational record and climate change make understanding the probabilities and characteristics of the most extreme events challenging. We will combine machine learning methods with novel rare event simulation methods to investigate the most extreme possible UK droughts.

Supervisors

• Jeroen Wouters (University of Reading)
• Laura Baker (University of Reading and National Centre for Atmospheric Science)
• Francesco Ragone (University of Leicester)
• Nick Dunstone (Met Office, UK)
• Eviatar Bach (University of Reading)

Partner

Met Office, UK

Building trust in AI forecasts for high-risk extreme events requires both confidence in their reliability and representation of underlying processes. This PhD project leverages explainable AI to assess physical plausibility, enhance confidence, understand forecast failures, and illuminate the "black-box" of AI models for forecasts of extreme weather events.

Supervisors

• Todd Jones (University of Reading)
• Ieuan Higgs (University of Reading)
• Kieran Hunt (University of Reading)
• Anna-Louise Ellis (Met Office, UK)

Partner

Met Office, UK

Earth system digital twins fuse machine learning models with real-world observations to predict the impact of policy choices on the environment and society under different scenarios. This project involves working at the intersection of applied mathematics, machine learning and climate science to develop next-generation digital twins that capture uncertainties in complex physical models, advancing these powerful tools for better-informed decision-making in a changing climate.

Supervisors

• Amos Lawless (University of Reading and National Centre for Earth Observation)
• Rossella Arcucci (Imperial College)
• Jennifer Scott (University of Reading)

Partner

National Centre for Earth Observation

UK water companies have a regulatory requirement to protect against severe drought, defined as a 1-in-200-year event. This project will develop defensible methods of testing this requirement using physical climate storylines (physically self-consistent, causal explanations) to construct plausible worst cases, anchored in downward counterfactuals of historical events.

Supervisors

• Ted Shepherd (University of Reading)
• Geoff Darch (Anglian Water)
• Kate Marvel (NASA GISS, USA)

Partner

Anglian Water