Rapid Phosphate Monitoring in Irish Freshwater Systems Using a Novel Microfluidic Colorimetric System

Rachel Bracker; Lisa Cronin; Aironas Grubliauskas; Louis Free; Joyce O’Grady; Sean Power; Karen Daly; Nigel Kent; Fiona Regan; Blánaid White

doi:https://doi.org/10.5194/egusphere-egu23-16201

[Back] [Session HS2.3.1]

EGU23-16201

https://doi.org/10.5194/egusphere-egu23-16201

EGU General Assembly 2023

© Author(s) 2023. This work is distributed under
the Creative Commons Attribution 4.0 License.

Rapid Phosphate Monitoring in Irish Freshwater Systems Using a Novel Microfluidic Colorimetric System

Rachel Bracker^1,2, Lisa Cronin^2,3, Aironas Grubliauskas^2,4, Louis Free^2,5, Joyce O’Grady^1,2, Sean Power^2,6, Karen Daly⁷, Nigel Kent^2,6, Fiona Regan^1,2, and Blánaid White^1,2

Rachel Bracker et al.

¹Dublin City University, School of Chemical Sciences, Dublin 9, Ireland
²Dublin City University, DCU Water Institute, Dublin 9, Ireland
³Centre for Environmental Research Innovation and Sustainability CERIS, Atlantic Technological University, Sligo, Ireland
⁴Dublin City University, School of Mechatronic Engineering, Dublin 9, Ireland
⁵Dublin City University, School of Electronic Engineering, Dublin 9, Ireland
⁶Dublin City University, School of Mechanical and Manufacturing Engineering, Dublin 9, Ireland
⁷Teagasc Food Research Centre, Johnstown Castle, Wexford, Ireland

The discharge of phosphorus associated with wastewater has decreased significantly in Europe over the past 25 years¹, however the problem of diffuse pollution persists². Studies have shown that regulatory monitoring can miss elevated spikes in phosphorus concentrations³ and high frequency monitoring is required⁴. Such programmes are resource intensive, requiring effective tools which enable appropriate water quality data collection and quality assurance⁵.

A low cost, portable, and rapid phosphate detection system is needed to enable the quick detection of phosphate in areas affected by high phosphate levels⁶. A new system is being developed by evolving a colorimetric detection system using microfluidic lab-on-a-disc technology which has previously been demonstrated⁷. It utilizes a micro-spectrometer and the molybdenum blue method, and has been built with the intent of requiring limited training.

The range of the system is 5-400 µg/L, which encompasses the threshold value of 35 µg/L P for Irish rivers and groundwaters⁸. The system is extremely portable due to its compact size and weighing less than 2 kg. With a run time of 15 minutes per ten samples, it enables the in-situ detection of phosphate for rapid on-site monitoring.

To test the system, rivers in the northwest of Ireland were identified. Three of these rivers have historical orthophosphate readings in the range of 5 - 47 µg/L and two others were reported considerably higher at 84 µg/L.

With this microfluidic phosphate detection system, rapid in-situ detection and reliable, real-time monitoring of phosphorus in freshwater systems can be achieved.

References:

1)European waters -- Assessment of status and pressures 2018 — European Environment Agency. https://www.eea.europa.eu/publications/state-of-water (accessed 2022-06-13).

2)Biddulph, M.; Collins, A. l.; Foster, I. d. l.; Holmes, N. The Scale Problem in Tackling Diffuse Water Pollution from Agriculture: Insights from the Avon Demonstration Test Catchment Programme in England. River Research and Applications 2017, 33 (10), 1527–1538. https://doi.org/10.1002/rra.3222.

3)Fones, G. R.; Bakir, A.; Gray, J.; Mattingley, L.; Measham, N.; Knight, P.; Bowes, M. J.; Greenwood, R.; Mills, G. A. Using High-Frequency Phosphorus Monitoring for Water Quality Management: A Case Study of the Upper River Itchen, UK. Environ Monit Assess 2020, 192 (3), 184. https://doi.org/10.1007/s10661-020-8138-0.

4)Bowes, M. J.; Palmer-Felgate, E. J.; Jarvie, H. P.; Loewenthal, M.; Wickham, H. D.; Harman, S. A.; Carr, E. High-Frequency Phosphorus Monitoring of the River Kennet, UK: Are Ecological Problems Due to Intermittent Sewage Treatment Works Failures? Environ. Monit. 2012, 14 (12), 3137–3145. https://doi.org/10.1039/C2EM30705G.

5)Quinn, N. W. T.; Dinar, A.; Sridharan, V. Decision Support Tools for Water Quality Management. Water 2022, 14 (22), 3644. https://doi.org/10.3390/w14223644.

6)Park J.; Kim, K. T.; Lee; W. H. Recent advances in information and communications technology (ICT) and sensor technology for monitoring water quality. 2020, Water, 12 (2)

7)O’Grady, J., Kent N., Regan, F. (2021). Design, build and demonstration of a fast, reliable portable phosphate field analyser. Case Stud. Chem. Environ. Eng., 2020, 4, 100168

8)Tierney, D.; O’Boyle, S. Water Quality in 2016: An Indicators Report; Environmental Protection Agency, Ireland: Wexford, 2018; p 48.

How to cite: Bracker, R., Cronin, L., Grubliauskas, A., Free, L., O’Grady, J., Power, S., Daly, K., Kent, N., Regan, F., and White, B.: Rapid Phosphate Monitoring in Irish Freshwater Systems Using a Novel Microfluidic Colorimetric System, EGU General Assembly 2023, Vienna, Austria, 24–28 Apr 2023, EGU23-16201, https://doi.org/10.5194/egusphere-egu23-16201, 2023.