Probability and Consequence of Postfire Erosion for Treatability of Water in an Unfiltered Supply System

Probability and Consequence of Postfire Erosion for Treatability of Water in an Unfiltered Supply System

Forested catchments are critical to water supply in major cities. Many of these catchments face the threat of postwildfire erosion, which can contaminate reservoir water. The aim of this paper is to determine the probability and duration of disruptions to treatability due to runoff‐generated debris...

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Veröffentlicht in:Water resources research 2021-01, Vol.57 (1), p.n/a
Hauptverfasser: Nyman, Petter, Yeates, Peter, Langhans, Christoph, Noske, Philip J., Peleg, Nadav, Schärer, Christine, Lane, Patrick N. J., Haydon, Shane, Sheridan, Gary J.
Format: Artikel
Sprache:eng
Schlagworte:
Catchment area
Catchments
Debris flow
Fluid mechanics
Headwaters
Hydrodynamics
Precipitation
Probability
Probability theory
Rainfall
reservoir hydrodynamics
Reservoir water
Reservoirs
Risk management
Runoff
Sediment
Sediment concentration
Stochasticity
Suspended sediments
treatability
Turbidity
Vegetation
Water conveyance
Water pollution
Water supply
Water supply systems
wildfire
Wildfires
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Zusammenfassung:Forested catchments are critical to water supply in major cities. Many of these catchments face the threat of postwildfire erosion, which can contaminate reservoir water. The aim of this paper is to determine the probability and duration of disruptions to treatability due to runoff‐generated debris flows in the first year after a wildfire, before substantial vegetation recovery takes place. We combine models of reservoir hydrodynamics, postfire erosion, and stochastic rainfall to determine probability and magnitude of sediment concentration at the reservoir water offtake. Central to the paper is our technique for linking model components into a risk framework that gives probabilities to the number of days that the turbidity threshold for treatment is exceeded. The model is applied to the Upper Yarra reservoir, which is the linchpin of the water supply system for Melbourne in SE Australia. However, the framework is applicable to other unfiltered water supply systems where suspended sediment is a risk to treatability. Results show that postwildfire erosion poses a substantial threat, with a relatively high probability (annual exceedance probability = 0.1–0.3) of water being untreatable for >1 year following a high‐severity wildfire. Important factors that influence the risk include postwildfire runoff potential, reservoir temperature, and the amount of clay‐sized grains in eroding headwaters. Assumptions about spatial‐temporal rainfall attributes, reservoir hydrodynamics, and the catchment erosion potential are all important sources of error in our estimate of risk. Our approach to risk quantification will help support planning, risk management, and strategic investment to mitigate impacts. Key Points Consequence of wildfire for an unfiltered water supply system is modeled based on erosion, stochastic rainfall, and reservoir hydrodynamics There is a 10–30% chance that water is untreatable for >1 year due to high suspended sediment concentration after a high‐severity wildfire Assumptions about spatiotemporal rainfall patterns, reservoir hydrodynamics, and erosion are all important sources of error in risk
ISSN:0043-1397
1944-7973
DOI:10.1029/2019WR026185