Advances on water quality modeling in burned areas: A review

Basso, Marta; Serpa, Dalila; Mateus, Marcos; Keizer, Jan Jacob; Vieira, Diana

doi:10.1371/journal.pwat.0000025

Cited by 10 publications

(4 citation statements)

References 82 publications

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“…Water providers, reservoir operators, land managers, and emergency response agencies would benefit from improved assessment and prediction of the character, magnitude, and duration of waterquality impacts after wildfire in watersheds across a wide range of ecoregions. A lack of adequate pre-and post-wildfire water-quality data hinders model calibration and adaptation (Basso et al, 2022), assessment of post-wildfire recovery (Hampton et al, 2022), and understanding how wildfires will affect regulatory requirements (Paul et al, 2022). Here we describe a path forward for strategic, consistent post-wildfire water-quality data collection for surface water that, when deployed across a range of ecosystems, will lead to vastly improved assessment and prediction of impacts of wildfire on water supplies.…”

Section: Introductionmentioning

confidence: 99%

“…In addition, because wildfires can reduce the threshold precipitation intensity at which overland flow occurs, post-wildfire stream discharge and sediment concentrations can be orders of magnitude greater than they would have been for similar storms pre-wildfire (Wondzell and King, 2003;Murphy et al, 2015), which poses challenges to current monitoring capabilities. As a result of these challenges, there are numerous gaps in post-wildfire water-quality data (Yu and Cheng, 2008;Rust et al, 2018;Basso et al, 2022;Hampton et al, 2022;Paul et al, 2022;Robinne et al, 2022;Raoelison et al, 2023), as shown in Figure 1.…”

Section: Introductionmentioning

confidence: 99%

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A call for strategic water-quality monitoring to advance assessment and prediction of wildfire impacts on water supplies

Murphy

Alpers²,

Anderson³

et al. 2023

Front. Water

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Wildfires pose a risk to water supplies in the western U.S. and many other parts of the world, due to the potential for degradation of water quality. However, a lack of adequate data hinders prediction and assessment of post-wildfire impacts and recovery. The dearth of such data is related to lack of funding for monitoring extreme events and the challenge of measuring the outsized hydrologic and erosive response after wildfire. Assessment and prediction of post-wildfire surface water quality would be strengthened by the strategic monitoring of key parameters, and the selection of sampling locations based on the following criteria: (1) streamgage with pre-wildfire data; (2) ability to install equipment that can measure water quality at high temporal resolution, with a focus on storm sampling; (3) minimum of 10% drainage area burned at moderate to high severity; (4) lack of major water management; (5) high-frequency precipitation; and (6) availability of pre-wildfire water-quality data and (or) water-quality data from a comparable unburned basin. Water-quality data focused on parameters that are critical to human and (or) ecosystem health, relevant to water-treatment processes and drinking-water quality, and (or) inform the role of precipitation and discharge on flow paths and water quality are most useful. We discuss strategic post-wildfire water-quality monitoring and identify opportunities for advancing assessment and prediction. Improved estimates of the magnitude, timing, and duration of post-wildfire effects on water quality would aid the water resources community prepare for and mitigate against impacts to water supplies.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A call for strategic water-quality monitoring to advance assessment and prediction of wildfire impacts on water supplies

Murphy

Alpers²,

Anderson³

et al. 2023

Front. Water

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“…Data-driven models often have lower data requirements than physical models, offering a unique opportunity to deepen understanding 16 . Studies using these techniques for post-fire water quality analysis 4,[29][30][31][32][33][34][35] have been relatively narrow in scope, for example, neglecting sediment, DOM, and nutrient responses across western U.S. Here, we apply data-driven methods to quantify postfire water quality signals across a wide range of constituents, evaluating a large sample of watersheds over several decades.…”

mentioning

confidence: 99%

Wildfires drive multi-year water quality degradation over the western U.S.

Brucker,

Livneh,

Rosario-Ortiz

et al. 2024

Preprint

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Wildfires can dramatically alter water quality with severe implications for human and freshwater systems. Although regional assessments of these effects can aid water managers in mitigation efforts, analyses to date have been limited by water quality data availability. Here, we unify observations from 245 burned catchments across the western U.S., applying a novel analytical framework to compare post-fire signals to baseline levels from 293 unburned basins for the period 1984–2021. Carbon, phosphorus, and turbidity exhibit significantly elevated levels (p ≤ 0.05) in the first 1–6 years post-fire, while nitrogen and sediment show significant increases up to 8 years post-fire. In each constituents’ peak post-fire response year, average loads of carbon, nitrogen, and phosphorus are 7–110 times pre-fire levels and sediment and turbidity 25–500 times greater than pre-fire. Higher responses are linked with greater forested and developed areas, with these characteristics respectively explaining up to 75 and 45% of inter-basin response variability. Overall, this analysis provides strong evidence of multi-year water quality degradation following wildfires in the U.S. West, as well as the influence of basin and wildfire features. These insights will aid in assessing watersheds’ vulnerability to the impacts of future wildfires.

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“…It is hypothesized that the key model input that represents fire in the GBR water quality models (in lieu of a model specifically adapted for fire) is the remotely sensed seasonal ground cover dataset, used to represent the cover factor (C-factor) in the calculation of hillslope erosion via the Revised Universal Soil Loss Equation (RUSLE). Land cover change is the most widely applied water quality model adaptation to represent fire impacts (Basso et al, 2022).…”

mentioning

confidence: 99%

Fire, fine sediment, and fractional ground cover: Representation of fire in the Cape York � Great Barrier Reef water quality model

2023

MODSIM2023, 25th International Congress on Modelling and Simulation.

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While there has been a long history of fires in northern Australia, including Indigenous burning for land management, Cape York has been experiencing an increase in extensive, intense, late dry season wildfires. Increases in 'megafires', globally, is being driven by increases in extremes under a changing climate. Wildfires can impact water quality through increased erosion risk, changed flow dynamics, and an increase in nutrient exports including carbon. The challenge for Cape York land managers is to use knowledge-based fire management to minimise wildfire occurrence, reduce carbon emissions, maintain biodiversity, and land condition. With targets set for water quality draining from the Cape York region to the Great Barrier Reef, focus has turned to how fire impacts ground cover dynamics, erosion processes, and water quality in the region. This paper aims to answer two questions; whether there are detectable changes in ground cover data because of fire and whether changes to erosion rates due to burning are represented in water quality models. A desktop assessment has been undertaken using the available spatial data, including remotely sensed ground cover data to evaluate the representation of known fire scars. Erosion rates were assessed using the Cape York water quality model over a specific study area and time-period to determine what impact, if any, fires have on fine sediment generation. This study concluded that fire scars are represented in the ground cover data which are used in the calculation of hillslope erosion in the Cape York water quality model. The main trends in ground cover change due to fire are represented in the model, however finer details about the duration and timing of cover change were beyond the scope of this study. It was determined that the key variables in determining the potential magnitude of soil loss are the timing and extent of low ground cover relative to the duration, timing, and intensity of post-fire rainfall. The highest water quality risk is associated with low ground cover, steep terrain, erodible soils, and high intensity rainfall. A future improvement for representing fire scars in the water quality models may be achieved through the incorporation of higher spatial and temporal resolution satellite imagery (e.g., using Sentinel derived products compared to Landsat).

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Advances on water quality modeling in burned areas: A review

Cited by 10 publications

References 82 publications

A call for strategic water-quality monitoring to advance assessment and prediction of wildfire impacts on water supplies

A call for strategic water-quality monitoring to advance assessment and prediction of wildfire impacts on water supplies

Wildfires drive multi-year water quality degradation over the western U.S.

Fire, fine sediment, and fractional ground cover: Representation of fire in the Cape York � Great Barrier Reef water quality model

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