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Enhanced Hydrologic Connectivity and Solute Dynamics Following Wildfire and Drought in a Contaminated Temperate Peatland Catchment

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Enhanced Hydrologic Connectivity and Solute Dynamics Following Wildfire and Drought in a Contaminated Temperate Peatland Catchment. / Marcotte, Abbey L.; Limpens, Juul; Nunes, João Pedro et al.
In: Water Resources Research, Vol. 60, No. 7, e2023WR036412, 01.07.2024.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Marcotte, AL, Limpens, J, Nunes, JP, Howard, BC, Hurley, AG, Khamis, K, Krause, S, Croghan, D, Kourmouli, A, Leader, S, Singh, T, Stoof, CR, Ullah, S & Kettridge, N 2024, 'Enhanced Hydrologic Connectivity and Solute Dynamics Following Wildfire and Drought in a Contaminated Temperate Peatland Catchment', Water Resources Research, vol. 60, no. 7, e2023WR036412. https://doi.org/10.1029/2023wr036412

APA

Marcotte, A. L., Limpens, J., Nunes, J. P., Howard, B. C., Hurley, A. G., Khamis, K., Krause, S., Croghan, D., Kourmouli, A., Leader, S., Singh, T., Stoof, C. R., Ullah, S., & Kettridge, N. (2024). Enhanced Hydrologic Connectivity and Solute Dynamics Following Wildfire and Drought in a Contaminated Temperate Peatland Catchment. Water Resources Research, 60(7), Article e2023WR036412. https://doi.org/10.1029/2023wr036412

Vancouver

Marcotte AL, Limpens J, Nunes JP, Howard BC, Hurley AG, Khamis K et al. Enhanced Hydrologic Connectivity and Solute Dynamics Following Wildfire and Drought in a Contaminated Temperate Peatland Catchment. Water Resources Research. 2024 Jul 1;60(7):e2023WR036412. Epub 2024 Jun 27. doi: 10.1029/2023wr036412

Author

Marcotte, Abbey L. ; Limpens, Juul ; Nunes, João Pedro et al. / Enhanced Hydrologic Connectivity and Solute Dynamics Following Wildfire and Drought in a Contaminated Temperate Peatland Catchment. In: Water Resources Research. 2024 ; Vol. 60, No. 7.

Bibtex

@article{54dce5a995ec4ecbb7c6f10d46654e3f,
title = "Enhanced Hydrologic Connectivity and Solute Dynamics Following Wildfire and Drought in a Contaminated Temperate Peatland Catchment",
abstract = "Intact peatlands provide hydrological ecosystem services, such as regulating water regimes and immobilizing pollutants within catchments. Climate change impacts including drought and wildfire may impair their functioning, potentially impacting ecosystem service delivery. Here we investigate stream water quality changes following the combined impacts of a summer drought and wildfire in a peat‐dominated catchment in the UK during 2018. The study catchment stores legacy pollutants (i.e., metals) due to past industrial activity, thus making it particularly susceptible to pollutant release during wildfires. We quantified changes in water chemistry during five storm events over a 9‐month period following the wildfire. Concentration‐discharge (C‐Q) relationships for nine solutes were analyzed to explore changes in activation and connectivity of solute source zones. Hysteresis and flushing indices of C‐Q responses further described solute dynamics during storm events. We found that most nutrient and base cation concentrations in the stream discharge were highest in the immediate post‐fire storm events and decreased during subsequent autumn and spring storms. Metal concentrations increased during autumn and spring storms, indicating delayed mobilization from within‐peat or distal headwater sources. Our findings suggest that seasonal re‐wetting and hydrologic connectivity following disturbance influenced solute source zone activation and transport in the study catchment. Water quality responses associated with wildfire and drought were primarily observed in the months following the wildfire, suggesting mobilization of pollutants peaks shortly after fire. Our results contribute to a critical understanding of the future of water quality risks in temperate peatland catchments subject to disturbances exacerbated by climate change.",
keywords = "concentration‐discharge relationship, heavy metals, blanket peatland, hysteresis, legacy pollutants",
author = "Marcotte, {Abbey L.} and Juul Limpens and Nunes, {Jo{\~a}o Pedro} and Howard, {Ben C.} and Hurley, {Alexander G.} and Kieran Khamis and Stefan Krause and Danny Croghan and Angeliki Kourmouli and Samantha Leader and Tanu Singh and Stoof, {Cathelijne R.} and Sami Ullah and Nicholas Kettridge",
year = "2024",
month = jul,
day = "1",
doi = "10.1029/2023wr036412",
language = "English",
volume = "60",
journal = "Water Resources Research",
issn = "0043-1397",
publisher = "AMER GEOPHYSICAL UNION",
number = "7",

}

RIS

TY - JOUR

T1 - Enhanced Hydrologic Connectivity and Solute Dynamics Following Wildfire and Drought in a Contaminated Temperate Peatland Catchment

AU - Marcotte, Abbey L.

AU - Limpens, Juul

AU - Nunes, João Pedro

AU - Howard, Ben C.

AU - Hurley, Alexander G.

AU - Khamis, Kieran

AU - Krause, Stefan

AU - Croghan, Danny

AU - Kourmouli, Angeliki

AU - Leader, Samantha

AU - Singh, Tanu

AU - Stoof, Cathelijne R.

AU - Ullah, Sami

AU - Kettridge, Nicholas

PY - 2024/7/1

Y1 - 2024/7/1

N2 - Intact peatlands provide hydrological ecosystem services, such as regulating water regimes and immobilizing pollutants within catchments. Climate change impacts including drought and wildfire may impair their functioning, potentially impacting ecosystem service delivery. Here we investigate stream water quality changes following the combined impacts of a summer drought and wildfire in a peat‐dominated catchment in the UK during 2018. The study catchment stores legacy pollutants (i.e., metals) due to past industrial activity, thus making it particularly susceptible to pollutant release during wildfires. We quantified changes in water chemistry during five storm events over a 9‐month period following the wildfire. Concentration‐discharge (C‐Q) relationships for nine solutes were analyzed to explore changes in activation and connectivity of solute source zones. Hysteresis and flushing indices of C‐Q responses further described solute dynamics during storm events. We found that most nutrient and base cation concentrations in the stream discharge were highest in the immediate post‐fire storm events and decreased during subsequent autumn and spring storms. Metal concentrations increased during autumn and spring storms, indicating delayed mobilization from within‐peat or distal headwater sources. Our findings suggest that seasonal re‐wetting and hydrologic connectivity following disturbance influenced solute source zone activation and transport in the study catchment. Water quality responses associated with wildfire and drought were primarily observed in the months following the wildfire, suggesting mobilization of pollutants peaks shortly after fire. Our results contribute to a critical understanding of the future of water quality risks in temperate peatland catchments subject to disturbances exacerbated by climate change.

AB - Intact peatlands provide hydrological ecosystem services, such as regulating water regimes and immobilizing pollutants within catchments. Climate change impacts including drought and wildfire may impair their functioning, potentially impacting ecosystem service delivery. Here we investigate stream water quality changes following the combined impacts of a summer drought and wildfire in a peat‐dominated catchment in the UK during 2018. The study catchment stores legacy pollutants (i.e., metals) due to past industrial activity, thus making it particularly susceptible to pollutant release during wildfires. We quantified changes in water chemistry during five storm events over a 9‐month period following the wildfire. Concentration‐discharge (C‐Q) relationships for nine solutes were analyzed to explore changes in activation and connectivity of solute source zones. Hysteresis and flushing indices of C‐Q responses further described solute dynamics during storm events. We found that most nutrient and base cation concentrations in the stream discharge were highest in the immediate post‐fire storm events and decreased during subsequent autumn and spring storms. Metal concentrations increased during autumn and spring storms, indicating delayed mobilization from within‐peat or distal headwater sources. Our findings suggest that seasonal re‐wetting and hydrologic connectivity following disturbance influenced solute source zone activation and transport in the study catchment. Water quality responses associated with wildfire and drought were primarily observed in the months following the wildfire, suggesting mobilization of pollutants peaks shortly after fire. Our results contribute to a critical understanding of the future of water quality risks in temperate peatland catchments subject to disturbances exacerbated by climate change.

KW - concentration‐discharge relationship

KW - heavy metals

KW - blanket peatland

KW - hysteresis

KW - legacy pollutants

U2 - 10.1029/2023wr036412

DO - 10.1029/2023wr036412

M3 - Journal article

VL - 60

JO - Water Resources Research

JF - Water Resources Research

SN - 0043-1397

IS - 7

M1 - e2023WR036412

ER -