Kenneth Porter

‌‌PhD Research Student (Catchment Microbial Dynamics)

MSc Environmental Management (The University of Stirling)
BSc (Hons) Environmental Biology (Edinburgh Napier University) 

Dr David Oliver (University of Stirling)
Dr Richard Quilliam (University of Stirling)
Dr Sim Reaney (Durham University)

Start Date: 1st October 2014

4V5 Cottrell Building
Biological & Environmental Sciences
Faculty of Natural Sciences
University of Stirling
Stirling, Scotland, FK9 4LA

tel: +44 (0)1786 467794
fax: +(44) 1786 467843 
twitter: @Kenneth_Porter

Research Project

Risk-based modelling of pathogen export from agricultural catchments under a changing climate

Diffuse pollution from agriculture presents a risk to microbial water quality and the security of ecosystem surfaces linked to clean and safe drinking water. This risk is likely to rise as the frequency and intensity of storm events increases, largely as a result of climate change. SCIMAP is an existing risk-mapping framework that has been successfully developed and deployed by the catchment management community to predict fine sediment and nutrient risk to watercourses. The SCIMAP approach is built on the premise that sources of pollution are only a risk to watercourses when they are hydrologically connected through the landscape to an aquatic receptor – this recognises the well-established diffuse pollution concept of critical source areas. In this project SCIMAP will be modified to optimise it for prediction of  faecal indicator organism (FIO) risk to receiving waters. Key challenges for SCIMAP FIO are to account for the temporal variations in FIO risk due to the dynamic survival patterns of microbial pollutants in the environment and to derive travel times from source to water bodies for FIOs and pathogens too. We will then explore the framework with different scenarios of climate and land-use change to predict how the risk of microbial pollution from agriculture might change in the future.

Key research questions:

1) How do hydrological pathways that connect pathogen source to receptor vary in space and time across different catchment typologies and how does this impact on microbial travel times?

2) To what extent does the probability of microbial die-off vary for different environmental conditions during transfer from catchment source to aquatic receptor?

3) How do we integrate microbial behavioural characteristics (both indicator and pathogen) into the SCIMAP framework to develop a conceptual and procedural risk-based model?

4) How will the export of microbial pollutants from the landscape alter under projected climate change?

Funding Acknowledgements

The PhD is funded by NERC via the IAPETUS Doctoral Training Partnership. My host institutions are The University of Stirling and Durham University.

© University of Stirling FK9 4LA Scotland UK • Telephone +44 1786 473171 • Scottish Charity No SC011159
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