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This PhD is being advertised as part of the Centre for Doctoral Training for Resilient Flood Futures (FLOOD-CDT). Further details about FLOOD-CDT can be seen here https://flood-cdt.ac.uk/
Project description
Coastal flooding is the second largest non-malicious risk to the UK. Accurate coastal forecast information is critical to enabling EA Incident Managers to assess coastal flood risk in real time and take appropriate mitigating actions.
Coastal water level forecast errors are currently twice the target accuracy in key locations due to complex local coastal processes. Forecast uncertainty at Thames Barrier, for example, forces operational teams to be overly cautious and more frequently close the barrier. This increases the probability of closures (together with sea level rise) exceeding that which is feasible before early 2030s, at which point a multi-billion pound upgrade will be needed. EA water level forecasts are based on a dynamical ocean model. This approach is skillful away from the coast but is fundamentally limited in effectiveness at the coastline, where processes are complex. Remnant errors/model bias have necessitated post-processing of raw model outputs. Current post processing techniques are simplistic and focus on correcting long-term bias. By contrast, machine learning techniques better represent error from complex or poorly understood processes and constrain model trajectories to real time observations. Machine learning techniques have shown promising potential to make a significant contribution to surge forecast skill but have yet to be explored in an operational context by the EA.
Methodology
In the first year, the student will review:
1) Storm surge dynamics. NOC will develop the student’s knowledge through hosting the PhD, as international leading experts in storm surge modelling and tidal analysis.
2) Requirements for operational forecasting. The student will work with MO/EA supervisors to identify key challenges and case studies, including operational considerations that shape forecast performance.
3) Available data and tools. The student will familiarise themselves with these aiming for use in following years - supported by all supervisors, including Southampton University who provide expertise in analysing and interpreting the observational record. The PhD will have access to operational surge model, tidal prediction and observational data (e.g. tide, river, mean sea level, meteorological).
Key activities will include (lead support):
• Investigate the role of tidal harmonics and bed friction in complex coastal environments (NOC)
• Develop metrics to assess existing model skill (EA)
• Run existing surge machine learning code to explore process and principles (NOC)
• Review modelling and machine learning tools and techniques (NOC/MO)
• Review observational data handling, challenges and quality control (SU).
Following years will develop a machine learning problem which addresses a challenge identified in year one, provide a proof of concept for operational implementation including success evaluation.
Entry requirements:
You must have a UK 2:1 honours degree or higher in a relevant subject.
See international equivalent qualifications on our website. English language: IELTS 6.5 overall, with a minimum of 6.0 in all components. We accept other English language tests.
How to apply
Apply online here. Please enter the project title and lead supervisor’s name in Section 2 to state which project you would like to apply for.
Applications should include:
· curriculum vitae giving details of your academic record and stating your research interests
· name two current academic referees together with an institutional email addresses in the Reference section of the application form. On submission of your online application your referees will be automatically emailed requesting they send a reference to us directly by email.
· your academic transcript and degree certificate (translated if not in English) - if you have completed both a BSc & an MSc, we require both.
· IELTS/TOEFL certificate, if applicable. For more information, please see the University of Southampton's English Language Proficiency page.
· include a short statement of your research interests in flooding and Flood-CDT and rationale for your choice of project(s) in the Personal Statement section of the application form.
Please ensure that you provide all required documentation and information so that your application can be reviewed and processed.
Please upload all documents in PDF format. You are encouraged to contact potential supervisors by email to discuss project-specific aspects of the proposed prior to submitting your application. If you have any general questions please contact floodcdt@soton.ac.uk.
The studentship will cover UK course fees and an enhanced tax-free stipend for 3.5 years along with a budget for research, travel, and placement activities. Details of the studentship amount can be found on the NERC web-site: View Website
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Research output data provided by the Research Excellence Framework (REF)
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