2019–2020 Bushfire impacts on sediment and contaminant transport following rainfall in the Upper Murray River catchment

Biswas, T.K.; Karim, Fazlul; Kumar, Anu; Wilkinson, Scott N.; Guerschman, Juan Pablo; Rees, Gavin N.; McInerney, Paul; Zampatti, Brenton P.; Sullivan, Andrew L.; Nyman, Petter; Sheridan, Gary; Joehnk, Klaus

doi:10.1002/ieam.4492

Cited by 15 publications

(13 citation statements)

References 43 publications

(60 reference statements)

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“…In addition, our model addresses how sediment threat in waterways is affected by interactions between time since fire, fire severity and soil and topographical properties (Cawson et al, 2016). More complex modelling approaches that focus on modifying the parameters of the RUSLE model to reflect the changing conditions of the post‐fire environment may be more powerful if current case studies can be extrapolated to larger scales (Biswas et al, 2021).…”

Section: Discussionmentioning

confidence: 99%

“…These highly visible soil, debris and ash sludges in waterways can cause high rates of immediate mortality and/or long‐term changes in waterway habitat. Sediment slugs arise because fires followed by rain can cause sediment influxes to waterways that are many times greater than pre‐fire (Biswas et al, 2021; Smith et al, 2011). To create a spatial model for post‐fire sedimentation threat for all rivers, streams and lakes (hereafter, waterways) within the study region, we built on the Revised Universal Soil Loss Equation (RUSLE; Renard et al, 1997; Renard & Freimund, 1994) by also considering fire extent and severity, and rainfall events likely to cause surface run‐off (and thus transport of sediment into waterways).…”

Section: Methodsmentioning

confidence: 99%

“…Note that these rankings do not predict the actual post‐fire sediment load in waterways and how sediment changes over time, nor do they consider the potential interactions between fire severity and the key soil and topographical variables. More complex modelling that considers these issues has been carried out at the sub‐catchment scale (Biswas et al, 2021), but is not yet possible at the scale of our study region. Our aim instead was to create a tool that could be used to quickly estimate the spatial extent of the threat of post‐fire sedimentation and use these data to inform rapid conservation interventions, such as fish rescues (Shelley et al, 2021), and conservation status assessments (Legge, Rumpff, et al, 2022).…”

Section: Methodsmentioning

confidence: 99%

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Modelling the spatial extent of post‐fire sedimentation threat to estimate the impacts of fire on waterways and aquatic species

Ward

Southwell

Gallagher

et al. 2022

Diversity and Distributions

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Aim: Fires can severely impact aquatic fauna, especially when attributes of soil, topography, fire severity and post-fire rainfall interact to cause substantial sedimentation. Such events can cause immediate mortality and longer-term changes in food resources and habitat structure. Approaches for estimating fire impacts on terrestrial species (e.g. intersecting fire extent with species distributions) are inappropriate for aquatic species as sedimentation can carry well downstream of the fire extent, and occur long after fire. Here, we develop an approach for estimating the spatial extent of fire impacts for aquatic systems, across multiple catchments.Location: Southern Australian bioregions affected by the fires in 2019-2020 that burned >10 million ha of temperate and subtropical forests. Methods:We integrated an existing soil erosion model with fire severity mapping and rainfall data to estimate the spatial extent of post-fire sedimentation threat in

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Modelling the spatial extent of post‐fire sedimentation threat to estimate the impacts of fire on waterways and aquatic species

Ward

Southwell

Gallagher

et al. 2022

Diversity and Distributions

Self Cite

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“…However, in recent decades, large and high severity wildfires have become more common in locations that historically burned at low intensity (Deb et al., 2020; Williams et al., 2019; Xu et al., 2021). These fire regime shifts can transform ecosystem dynamics and structure, increase air and water pollution, cause flood and landslide hazards, and threaten human property and lives (Biswas et al., 2021; Bowman et al., 2009; Kemter et al., 2021; Smith et al., 2016). To mitigate future wildfire risk in the wildland urban interface, and to predict fire hazard across wildlands, forest managers need to better understand how climate change and wildfire interact at scales where management actions are implemented.…”

Section: Introductionmentioning

confidence: 99%

“…and threaten human property and lives (Biswas et al, 2021;Bowman et al, 2009;Kemter et al, 2021;Smith et al, 2016). To mitigate future wildfire risk in the wildland urban interface, and to predict fire hazard across wildlands, forest managers need to better understand how climate change and wildfire interact at scales where management actions are implemented.…”

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confidence: 99%

Projecting Future Fire Regimes in a Semiarid Watershed of the Inland Northwestern United States: Interactions Among Climate Change, Vegetation Productivity, and Fuel Dynamics

et al. 2022

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Fire regimes are influenced by both exogenous drivers (e.g., increases in atmospheric CO2 and climate change) and endogenous drivers (e.g., vegetation and soil/litter moisture), which constrain fuel loads and fuel aridity. Herein, we identified how exogenous and endogenous drivers can interact to affect fuels and fire regimes in a semiarid watershed in the inland northwestern United States throughout the 21st century. We used a coupled ecohydrologic and fire regime model to examine how climate change and CO2 scenarios influence fire regimes. In this semiarid watershed, we found an increase in burned area and burn probability in the mid‐21st century (2040s) as the CO2 fertilization effect on vegetation productivity outstripped the effects of climate change‐induced fuel decreases, resulting in greater fuel loading. However, by the late‐21st century (2070s), climatic warming dominated over CO2 fertilization, thus reducing fuel loading and burned area. Fire regimes were shown to shift from flammability‐ to fuel‐limited or become increasingly fuel‐limited in response to climate change. We identified a metric to identify when fire regimes shift from flammability‐ to fuel‐limited: the ratio of the change in fuel loading to the change in its aridity. The threshold value for which this metric indicates a flammability versus fuel‐limited regime differed between grasses and woody species but remained stationary over time. Our results suggest that identifying these thresholds in other systems requires narrowing uncertainty in exogenous drivers, such as future precipitation patterns and CO2 effects on vegetation.

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Summer odors to winter blooms: Treatment validation in the lower River Murray

2023

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A 12-event survey of 8 water treatment plants (WTPs) was conducted to determine the impact of the 2021 summer (January) to winter (August) cyanobacterial challenge on WTP performance. High cyanobacterial numbers (>20,000 cells/ mL) and high taste and odor (T&O) concentrations (>100 ng/L) were encountered. The summer to winter transition of this cyanobacterial challenge also saw the proliferation of Pseudanabaena blooms which challenged conventional WTPs and a breakthrough of cells was detected. This required further investigation into optimizing Pseudanabaena removal in WTP processes. WTP sampling determined that the sludge lagoons provided conducive conditions for cell accumulation and metabolite release. These cells and T&O compounds were recycled back into the head of the WTP through the supernatant return flows. In the most extreme case, 512 ng/L of T&O compounds was detected in the supernatant return. This study highlighted the need to understand the potential risks that treatment plants can encounter and ensure appropriate management during and after cyanobacterial events.

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2019–2020 Bushfire impacts on sediment and contaminant transport following rainfall in the Upper Murray River catchment

Cited by 15 publications

References 43 publications

Modelling the spatial extent of post‐fire sedimentation threat to estimate the impacts of fire on waterways and aquatic species

Modelling the spatial extent of post‐fire sedimentation threat to estimate the impacts of fire on waterways and aquatic species

Projecting Future Fire Regimes in a Semiarid Watershed of the Inland Northwestern United States: Interactions Among Climate Change, Vegetation Productivity, and Fuel Dynamics

Summer odors to winter blooms: Treatment validation in the lower River Murray

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