Road-Ready

Design and Implementation of Mitigation Measure Toolbox to Disconnect Farm Roadway Runoff Nutrient Losses from Waters

Relatively small but critical source areas within agricultural catchments tend to contribute disproportionally to nutrient concentrations in receiving waters, and require identification followed by targeted remediation strategies. Farm roadways typically retain excessive nutrient concentrations, particularly phosphorus (P), and have been little investigated with respect to their role in nutrient transport to receiving waters. Critical farm roadway sections are those that have all components of the nutrient transfer continuum, including source, mobilisation, transport, hydrological connectivity, delivery, and impact. Achieving water quality goals outlined by the EU Water Framework Directive requires reductions in nutrient point and diffuse sources, and mitigation of pathways delivering those nutrients to surface water receptors. There is therefore an urgent need to establish the effectiveness of roadway runoff mitigation measures and to develop a strategy of ‘right place, right management option’, particularly for existing critical roadway sections. The primary objective of the ROAD-READY project is to evaluate the extent and connectivity risk of farm roadway runoff to waters and assess effectiveness of a variety of mitigation and management options to break the pathway. The ROAD-READY project collaborates with farm and landowners within the Teagasc Heavy Soils Programme and Agricultural Catchment Programme (ACP).

Project Objectives

To measure and compare spatial and temporal available P concentrations within roadway substrate in different farm enterprises such as dairy and beef farms
To develop an automated/semi-automated connectivity risk assessment tool for farm roadway runoff to waters using a combination of novel techniques such as GIS and aerial imagery
To design and assess efficacy of on- and off-roadway mitigation and management options to reduce the negative impact of farm roadway runoff to waters.

Work to date

The first objective, which is to measure spatial and temporal P concentrations within farm roadway substrates on pastoral farms, has been completed. The spatial and temporal variability of the P concentrations was assessed and compared for dairy and beef farms for 8 months, covering the closed and open periods. Results indicated that P concentrations on the roadway substrates in both dairy and beef farms were elevated (greater than the P concentrations on soil from adjacent fields), especially on bends, underpasses and junctions, and forms a subcomponent of the nutrient transfer continuum. On the dairy farm, the P concentrations were up to 4 times greater than on the beef farms. The spatial and temporal signal of beef farms although lower than that of the dairy system was significant and therefore needs to be managed within critical source areas. Temporal data suggests that P is available all year round to be lost in roadway runoff. Highest concentrations are found during the open period but are sustained and start to decline over the closed period (due to lack of fresh deposits as cows are housed and frequent rainfall during that period) only to rise again once cows are given access to paddocks for grazing. Spatial distribution of P concentrations on roadway and trackway material was also assessed on a sheep farm for one-month data. Surprisingly, the P concentrations were high just like in the dairy farm – considerably higher compared to P in roadway substrates from the beef farms even though roadways are not extensively used in sheep farming. However, P source factors and the volume of excreta deposited on the roadway are determined by the stocking rate (about 4.5LU/ha for beef farms and 12LU/ha in the sheep farm in this case studies) and roadway density. Therefore, fresh excreta and nutrient enriched roadway materials are a labile P source and should be considered when implementing mitigation measures to break the pathway of roadway runoff to waters.

Published articles

A model is currently being developed to automatically detect farm roadways in a given farm, and thus, (together with other modelled factors) we would be able to map critical roadway sections that require mitigation. Below is preliminary results of a machine learning to detect farm roadways and trackways which was implemented in one of the beef farms in Johnstown Castle, Wexford.

Overhead image of a beef farm, showing ditches, grassland, and roadways in different colours

Teagasc Project Team

Prof Owen Fenton
Project PI and Co-ordinator based in Teagasc, Johnstown Castle

Based at Teagasc, Johnstown Castle. Principal Research Officer: Specialises in nitrogen and phosphorus characterisation and mitigation on agricultural landscapes. This work also investigates soil water management with an emphasis on soil hydrology and hydrogeology. PI of EU Interreg NWE Smart Carbon Farming related project.

Dr Pat Tuohy
Researcher, Teagasc Moorepark

Based in Teagasc, Moorepark. Senior Research Officer: Specialises in peatland hydrology, soil physical characterisation, soil water management. PI of related DAFM RSF 2021R454 REWET project.

Dr Karen Daly
Researcher, Head of Environment, Soils & Land Use Department, Teagasc Johnstown Castle

Based in Teagasc Johnstown Castle research centre, Karen is a researcher in environmental science and Head of the Environment, Soils and Land Use (ESLU) department. Her research group focuses on soil health, water quality, proximal sensing and spectroscopy, operating across multiple scales, namely: mechanistic processes for soil health at profile scale; the fate and transfer of pollutants at catchment scale; regional and national scale risk assessment for soil health and water quality, spectral sensing and isotope tracing.

Dr Russell Adams
Researcher, Teagasc Johnstown Castle

Based at Teagasc, Johnstown Castle. Research Officer. Russell is a hydrologist with a background in water quality modelling. He has also worked on different research topics in catchment science including monitoring and modelling sediment and nutrient loadings in agricultural catchments.

Lungile Senteni Sifundza
PhD Student

Lungile is a PhD student on the ROAD-READY project based at Teagasc, Johnstown Castle Research Centre and enrolled at the University of Limerick. She holds a Bachelor of Science in Agricultural and Biosystems Engineering from the University of Swaziland and a Master of Science in Water Resources Management from IHE Delft Institute for Water Education in the Netherlands. Her research interests include water quantity and quality management in agricultural landscapes and the global changes (land use and climate change) on hydrology and water resources.

Dr Luis Lopez-Sangil
Research Technologist

Based at Teagasc, Johnstown Castle. Soil Health research technologist. Luis has specialized in soil physics with a research background on soil organic matter (SOM) dynamics: He did his PhD on SOM mineralization in agricultural systems (University of Barcelona, Spain), and was postdoctoral researcher on carbon and nutrient cycling in forests (Lancaster University, UK), developing new methods for soil carbon analyses, SOM fractionation or root exudation. Luis is also developing drone surveys at Teagasc Johnstown Castle.

Gabriela Cardenas Alvarez
Technician

Gabriela is an Environmental Research Technician at Teagasc Johnstown Castle Research Centre, where she supports various environmental projects focused on emissions to water, soil, and air. As technician she ensures accurate execution of field and laboratory protocols, addressing issues that could affect sample quality while seeking innovative solutions to improve efficiency. Gabriela also contributes to the design and planning of fieldwork, establishing technical protocols for effective sample collection.

University of Limerick Project Team

Dr John Murnane

Specialises in resource recovery / bioremediation of contaminated wastewaters and in environmental sustainability. He is currently PI/CO-PI on several European (ERA-MIN) and national (EPA) projects and is course director for BE and ME civil engineering programmes at UL.