Near real-time monitoring of post-fire erosion after storm events: a case study in Warrumbungle National Park, Australia
Xihua Yang A D E , Qinggaozi Zhu B D , Mitch Tulau A , Sally McInnes-Clarke A , Liying Sun C and Xiaoping Zhang DA New South Wales Office of Environment and Heritage, PO Box A290, Sydney South, NSW 1232, Australia.
B School of Life Sciences, University of Technology Sydney, PO Box 123, Broadway, NSW 2007, Australia.
C Key Laboratory of Water Cycle and Related Land Surface Processes, Institute of Geographical Sciences and Natural Resources Research, Chinese Academy of Sciences, Beijing, 100101, PR China.
D State Key Laboratory of Soil Erosion and Dryland Farming on the Loess Plateau, Institute of Soil and Water Conservation, Northwest A&F University, Yangling, Shaanxi, 712100, PR China.
E Corresponding author. Email: xihua.yang@environment.nsw.gov.au
International Journal of Wildland Fire 27(6) 413-424 https://doi.org/10.1071/WF18011
Submitted: 30 January 2018 Accepted: 26 April 2018 Published: 5 June 2018
Abstract
Wildfires in national parks can lead to severe damage to property and infrastructure, and adverse impacts on the environment. This is especially pronounced if wildfires are followed by intense storms, such as the fire in Warrumbungle National Park in New South Wales, Australia, in early 2013. The aims of this study were to develop and validate a methodology to predict erosion risk at near real-time after storm events, and to provide timely information for monitoring of the extent, magnitude and impact of hillslope erosion to assist park management. We integrated weather radar-based estimates of rainfall erosivity with the revised universal soil loss equation (RUSLE) and remote sensing to predict soil loss from individual storm events after the fire. Other RUSLE factors were estimated from high resolution digital elevation models (LS factor), satellite data (C factor) and recent digital soil maps (K factor). The accuracy was assessed against field measurements at twelve soil plots across the Park and regular field survey during the 5-year period after the fire (2013–17). Automated scripts in a geographical information system have been developed to process large quantity spatial data and produce time-series erosion risk maps which show spatial and temporal changes in hillslope erosion and groundcover across the Park at near real time.
Additional keywords: geographic information system, rainfall erosivity, remote sensing, soil loss, weather radar.
References
ABC (2013) A timeline of the Coonabarabran bushfires. Available at http://www.abc.net.au/local/stories/2013/02/13/3689707.htm [Verified 22 February 2017]Atkinson G (1984) Erosion damage following bushfires. Journal of Soil Conservation NSW 40, 4–9.
Blong RJ (1982) Sediment yield from runoff plots following bushfire near Narrabeen Lagoon, NSW. Search 13, 36–38.
Bradstock R, Penman T, Boer M, Price O, Clarke H (2014) Divergent responses of fire to recent warming and drying across south-eastern Australia. Global Change Biology 20, 1412–1428.
| Divergent responses of fire to recent warming and drying across south-eastern Australia.Crossref | GoogleScholarGoogle Scholar |
Brown LC, Foster GR (1987) Storm erosivity using idealized intensity distribution. Transactions of the ASAE. American Society of Agricultural Engineers 30, 0379–0386.
| Storm erosivity using idealized intensity distribution.Crossref | GoogleScholarGoogle Scholar |
Bureau of Meteorology (2016) State of the Climate 2016. Available at http://www.bom.gov.au/state-of-the-climate/ [Verified 18 May 2017]
Certini G (2005) Effects of fire on properties of forest soils: a review. Oecologica 143, 1–10.
| Effects of fire on properties of forest soils: a review.Crossref | GoogleScholarGoogle Scholar |
Chavez PS (1988) An improved dark-object subtraction technique for atmospheric scattering correction of multi-spectral data. Remote Sensing of Environment 24, 459–479.
| An improved dark-object subtraction technique for atmospheric scattering correction of multi-spectral data.Crossref | GoogleScholarGoogle Scholar |
Cruse R, Flanagan D, Frankenberger J, Gelder B, Herzmann D, James D, Krajewski W, Kraszewski M, Laflen J, Opsomer J, Todey D (2006) Daily estimates of rainfall, water runoff, and hillslope erosion in Iowa. Journal of Soil and Water Conservation 61, 191–199.
Dabney SM, Yoder DC, Dalmo ANV, Bingner RL (2011) Enhancing RUSLE to include runoff-driven phenomena. Hydrological Processes 25, 1373–1390.
| Enhancing RUSLE to include runoff-driven phenomena.Crossref | GoogleScholarGoogle Scholar |
Dutta R, Das A, Aryal J (2016) Big data integration shows Australian bush-fire frequency is increasing significantly. Royal Society Open Science 3, 150241
| Big data integration shows Australian bush-fire frequency is increasing significantly.Crossref | GoogleScholarGoogle Scholar |
Flanagan DC, Nearing MA (1995) USDA Water Erosion Prediction Project: Hillslope Profile and Watershed Model Documentation. USDA-ARS National Soil Erosion Research Laboratory, NSERL Report number 10. (West Lafayette, IN, USA)
Gallant JC, Dowling TI, Read AM, Wilson N, Tickle P, Inskeep C (2011) 1 second SRTM Derived Digital Elevation Models User Guide. (Geoscience Australia: Canberra, ACT, Australia) Available at www.ga.gov.au/topographic-mapping/digital-elevation-data.html [Verified 17 May 2018]
Gill AM, Stephens SL, Cary GJ (2013) The worldwide ‘wildfire’ problem. Ecological Applications 23, 438–454.
| The worldwide ‘wildfire’ problem.Crossref | GoogleScholarGoogle Scholar |
Gonzalez-Bonorino G, Osterkamp WR (2004) Applying RUSLE 2.0 on burned-forest lands: an appraisal. Journal of Soil and Water Conservation 59, 36–42.
Grundy MJ, Viscarra Rossel RA, Searle RD, Wilson PL, Chen C, Gregory LJ (2015) Soil and landscape grid of Australia. Soil Research 53, 835–844.
| Soil and landscape grid of Australia.Crossref | GoogleScholarGoogle Scholar |
Guerschman JP, Hill MJ, Renzullo LJ, Barrett DJ, Marks AS, Botha EJ (2009) Estimating fractional cover of photosynthetic vegetation, non-photosynthetic vegetation and bare soil in the Australian tropical savanna region upscaling the EO-1 Hyperion and MODIS sensors. Remote Sensing of Environment 113, 928–945.
| Estimating fractional cover of photosynthetic vegetation, non-photosynthetic vegetation and bare soil in the Australian tropical savanna region upscaling the EO-1 Hyperion and MODIS sensors.Crossref | GoogleScholarGoogle Scholar |
Haboudane D, Miller JR, Pattey E, Zarco-Tejada PJ, Strachan IB (2004) Hyperspectral vegetation indices and novel algorithms for predicting green LAI of crop canopies: Modeling and validation in the context of precision agriculture. Remote Sensing of Environment 90, 337–352.
| Hyperspectral vegetation indices and novel algorithms for predicting green LAI of crop canopies: Modeling and validation in the context of precision agriculture.Crossref | GoogleScholarGoogle Scholar |
Hammill KA, Bradstock RA (2006) Remote sensing of fire severity in the Blue Mountains: influence of vegetation type and inferring fire intensity. International Journal of Wildland Fire 15, 213–226.
| Remote sensing of fire severity in the Blue Mountains: influence of vegetation type and inferring fire intensity.Crossref | GoogleScholarGoogle Scholar |
Isbell RF, National Committee on Soil and Terrain (2016) ‘The Australian Soil Classification’, 2nd edn. (CSIRO Publishing: Melbourne, Vic., Australia)
IUSS Working Group WRB (2015) World reference base for soil resources 2014, update 2015 International soil classification system for naming soils and creating legends for soil maps. FAO, World Soil Resources Reports number 106. (Rome, Italy)
Kinnell PIA (2010) Event soil loss, runoff and the Universal Soil Loss family of models: a review. Journal of Hydrology 385, 384–397.
| Event soil loss, runoff and the Universal Soil Loss family of models: a review.Crossref | GoogleScholarGoogle Scholar |
Kinnell PIA (2014) Modelling event soil losses using the QREI30 index within RUSLE2. Hydrological Processes 28, 2761–2771.
| Modelling event soil losses using the QREI30 index within RUSLE2.Crossref | GoogleScholarGoogle Scholar |
Kinnell PIA (2017) A comparison of the abilities of the USLE-M, RUSLE2 and WEPP to model event erosion from bare fallow areas. The Science of the Total Environment 596–597, 32–42.
| A comparison of the abilities of the USLE-M, RUSLE2 and WEPP to model event erosion from bare fallow areas.Crossref | GoogleScholarGoogle Scholar |
Lane PNJ, Sheridan GJ, Noske PJ (2006) Changes in sediment loads and discharge from small mountain catchments following wildfire in southeastern Australia. Journal of Hydrology 331, 495–510.
| Changes in sediment loads and discharge from small mountain catchments following wildfire in southeastern Australia.Crossref | GoogleScholarGoogle Scholar |
Larsen IJ, MacDonald LH (2007) Predicting postfire sediment yields at the hillslope scale: testing RUSLE and Disturbed WEPP. Water Resources Research 43, W11412
| Predicting postfire sediment yields at the hillslope scale: testing RUSLE and Disturbed WEPP.Crossref | GoogleScholarGoogle Scholar |
Leitch C, Flinn D, van de Graaff R (1983) Erosion and nutrient loss resulting from Ash Wednesday (February 1983) wildfires: a case study. Australian Forestry 46, 173–180.
| Erosion and nutrient loss resulting from Ash Wednesday (February 1983) wildfires: a case study.Crossref | GoogleScholarGoogle Scholar |
Litschert SE, Theobald DM, Brown TC (2014) Effects of climate change and wildfire on soil loss in the Southern Rockies Ecoregion. Catena 118, 206–219.
| Effects of climate change and wildfire on soil loss in the Southern Rockies Ecoregion.Crossref | GoogleScholarGoogle Scholar |
Lu H, Prosser IP, Moran CJ, Gallant JC, Priestley G, Stevenson JG (2003) Predicting sheetwash and rill erosion over the Australian continent. Australian Journal of Soil Research 41, 1037–1062.
| Predicting sheetwash and rill erosion over the Australian continent.Crossref | GoogleScholarGoogle Scholar |
Marsett RC, Qi J, Heilman P, Biedenbender SH, Watson MC, Am S, Weltz M, Goodrich D, Marsett R (2006) Remote sensing for grassland management in the Arid Southwest. Rangeland Ecology and Management 59, 530–540.
| Remote sensing for grassland management in the Arid Southwest.Crossref | GoogleScholarGoogle Scholar |
McAneney J, Chen K, Pitman A (2009) 100-years of Australian bushfire property losses: is the risk significant and is it increasing? Journal of Environmental Management 90, 2819–2822.
| 100-years of Australian bushfire property losses: is the risk significant and is it increasing?Crossref | GoogleScholarGoogle Scholar |
Miller JD, Nyhan JW, Yool SR (2003) Modeling potential erosion due to the Cerro Grande fire with a GIS based implementation of the Revised Universal Soil Loss Equation. International Journal of Wildland Fire 12, 85–100.
| Modeling potential erosion due to the Cerro Grande fire with a GIS based implementation of the Revised Universal Soil Loss Equation.Crossref | GoogleScholarGoogle Scholar |
Moody JA, Ebel BA (2014) Infiltration and runoff generation processes in fire-affected soils. Hydrological Processes 28, 3432–3453.
| Infiltration and runoff generation processes in fire-affected soils.Crossref | GoogleScholarGoogle Scholar |
Moody JA, Martin DA (2009) Synthesis of sediment yields after wildland fire in different rainfall regimes in the western United States. International Journal of Wildland Fire 18, 96–115.
| Synthesis of sediment yields after wildland fire in different rainfall regimes in the western United States.Crossref | GoogleScholarGoogle Scholar |
Moody JA, Shakesby RA, Robichaud PR, Cannon SH, Martin DA (2013) Current research issues related to post-wildfire runoff and erosion processes. Earth-Science Reviews 122, 10–37.
| Current research issues related to post-wildfire runoff and erosion processes.Crossref | GoogleScholarGoogle Scholar |
Muir J, Schmidt M, Tindall D, Trevithick R, Scarth P, Stewart JB (2011) Field measurement of fractional ground cover: a technical handbook supporting ground cover monitoring for Australia, prepared by the Queensland Department of Environment and Resource Management for the Australian Bureau of Agricultural and Resource Economics and Sciences, Canberra, November.
Nash JE, Sutcliffe JV (1970) River flow forecasting through conceptual models, Part 1: a discussion of principles. Journal of Hydrology 10, 282–290.
| River flow forecasting through conceptual models, Part 1: a discussion of principles.Crossref | GoogleScholarGoogle Scholar |
Nearing MA, Pruski FF, O’Neal MR (2004) Expected climate change impacts on hillslope erosion rates: a review. Journal of Soil and Water Conservation 59, 43–50.
Noske PJ, Nyman P, Lane PNJ, Sheridan GJ (2016) Effects of aridity in controlling the magnitude of runoff and erosion after wildfire. Water Resources Research 52, 4338–4357.
| Effects of aridity in controlling the magnitude of runoff and erosion after wildfire.Crossref | GoogleScholarGoogle Scholar |
Nyman P, Sheridan GJ, Smith HG, Lane PNJ (2011) Evidence of debris flow occurrence after wildfire in upland catchments of south-east Australia. Geomorphology 125, 383–401.
| Evidence of debris flow occurrence after wildfire in upland catchments of south-east Australia.Crossref | GoogleScholarGoogle Scholar |
Nyman P, Sheridan GJ, Lane PN (2013) Hydro-geomorphic response models for burned areas and their applications in land management. Progress in Physical Geography 37, 787–812.
| Hydro-geomorphic response models for burned areas and their applications in land management.Crossref | GoogleScholarGoogle Scholar |
Nyman P, Smith HG, Sherwin CB, Langhans C, Lane PNJ, Sheridan GJ (2015) Predicting sediment delivery from debris flows after wildfire. Geomorphology 250, 173–186.
| Predicting sediment delivery from debris flows after wildfire.Crossref | GoogleScholarGoogle Scholar |
OEH (2017) Soil data. Available at http://www.environment.nsw.gov.au/soils/data.htm [Verified 5 February 2017]
Renard KG, Foster GR, Weesies GA, McCool DK, Yoder DC (1997) Predicting hillslope erosion by water: a guide to conservation planning with the Revised Universal Hillslope Erosion Equation (RUSLE). In ‘US Department of Agriculture, Agricultural Handbook. Vol. 703’. pp. 1–251. (USDA: Washington, DC, USA)
Riley SJ, Crozier P, Blong RJ (1981) An inexpensive and easily installed runoff plot. Journal of the Soil Conservation Service NSW 37, 144–147.
Risal A, Lim KJ, Bhattarai R, Yang JE, Noh H, Pathak R, Kim J (2018) Development of web-based WERM-S module for estimating spatially. Catena 161, 37–49.
| Development of web-based WERM-S module for estimating spatially.Crossref | GoogleScholarGoogle Scholar |
Robichaud PR (2000) Fire effects on infiltration rates after prescribed fire in Northern Rocky Mountain forests, USA. Journal of Hydrology 231–232, 220–229.
| Fire effects on infiltration rates after prescribed fire in Northern Rocky Mountain forests, USA.Crossref | GoogleScholarGoogle Scholar |
Robichaud PR, Ashmun LE (2013) Tools to aid post-wildfire assessment and erosion-mitigation treatment decisions. International Journal of Wildland Fire 22, 95–105.
| Tools to aid post-wildfire assessment and erosion-mitigation treatment decisions.Crossref | GoogleScholarGoogle Scholar |
Rulli MC, Offeddu L, Santini M (2013) Modeling post-fire water erosion mitigation strategies. Hydrology and Earth System Sciences 17, 2323–2337.
| Modeling post-fire water erosion mitigation strategies.Crossref | GoogleScholarGoogle Scholar |
Segura C, Sun G, McNulty S, Zhang Y (2014) Potential impacts of climate change on hillslope erosion vulnerability across the conterminous United States. Journal of Soil and Water Conservation 69, 171–181.
| Potential impacts of climate change on hillslope erosion vulnerability across the conterminous United States.Crossref | GoogleScholarGoogle Scholar |
Shakesby RA, Doerr SH (2006) Wildfire as a hydrological and geomorphological agent. Earth-Science Reviews 74, 269–307.
| Wildfire as a hydrological and geomorphological agent.Crossref | GoogleScholarGoogle Scholar |
Sheridan GJ, Nyman P, Langhans C, Cawson J, Noske PJ, Akiko O, Van der Sant R, Lane PNJ (2016) Is aridity a high-order control on the hydro–geomorphic response of burned landscapes? International Journal of Wildland Fire 25, 262–267.
| Is aridity a high-order control on the hydro–geomorphic response of burned landscapes?Crossref | GoogleScholarGoogle Scholar |
Sidman G, Guertin DP, Goodrich DC, Unkrich CL, Burns IS (2016) Risk assessment of post-wildfire hydrological response in semiarid basins: the effects of varying rainfall representations in the KINEROS2/AGWA model. International Journal of Wildland Fire 25, 268–278.
| Risk assessment of post-wildfire hydrological response in semiarid basins: the effects of varying rainfall representations in the KINEROS2/AGWA model.Crossref | GoogleScholarGoogle Scholar |
Smith HG, Sheridan GJ, Lane PNJ, Nyman P, Haydon S (2011) Wildfire effects on water quality in forest catchments: a review with implications for water supply. Journal of Hydrology 396, 170–192.
| Wildfire effects on water quality in forest catchments: a review with implications for water supply.Crossref | GoogleScholarGoogle Scholar |
Smith AM, Hill MJ, Zhang YQ (2015) Estimating ground cover in the mixed prairie grassland of southern Alberta using vegetation indices related to physiological function. Canadian Journal of Remote Sensing 41, 51–66.
| Estimating ground cover in the mixed prairie grassland of southern Alberta using vegetation indices related to physiological function.Crossref | GoogleScholarGoogle Scholar |
Storey M (2014) ‘Fire severity mapping for the Wambelong 2013 fire.’ (CEMB, The University of Wollongong: Wollongong, NSW, Australia)
Teng HF, Viscarra Rossel RA, Shi Z, Behrens T, Chappell A, Bui E (2016) Assimilating satellite imagery and visible-near infrared spectroscopy to model and map soil loss by water erosion in Australia. Environmental Modelling & Software 77, 156–167.
| Assimilating satellite imagery and visible-near infrared spectroscopy to model and map soil loss by water erosion in Australia.Crossref | GoogleScholarGoogle Scholar |
USDA (2008) Draft Science Documentation: Revised Universal Soil Loss Equation Version 2 (RUSLE2) USDA–Agricultural Research Service. (Washington, DC, USA) Available at http://fargo.nserl.purdue.edu/rusle2_dataweb/userguide/RUSLE2_User_Ref_Guide_2008.pdf [Verified 17 May 2018]
Veihe A, Rey J, Quinton JN, Strauss P, Sancho FM, Somarriba M (2001) Modeling of event-based hillslope erosion in Costa Rica, Nicaragua and Mexico: evaluation of the EUROSEM model. Catena 44, 187–203.
| Modeling of event-based hillslope erosion in Costa Rica, Nicaragua and Mexico: evaluation of the EUROSEM model.Crossref | GoogleScholarGoogle Scholar |
Weng QH (2014) ‘Scale issues in remote sensing.’ (Wiley: Chichester, UK)
Wischmeier WH, Smith DD (1978) Predicting rainfall erosion losses, a guide to conservation planning. US Department of Agriculture, Agricultural Handbook. Vol. 537. (Washington, DC, USA)
Yang X (2014) Deriving RUSLE cover factor from time-series fractional vegetation cover for hillslope erosion risk monitoring in New South Wales. Soil Research 52, 253–261.
| Deriving RUSLE cover factor from time-series fractional vegetation cover for hillslope erosion risk monitoring in New South Wales.Crossref | GoogleScholarGoogle Scholar |
Yang X (2015) Digital mapping of RUSLE slope length and steepness factor across New South Wales. Soil Research 53, 216–225.
Yang X, Yu BF (2015) Modelling and mapping rainfall erosivity in New South Wales, Australia. Soil Research 53, 178–189.
Yang X, Gray J, Chapman C, Zhu Q, Tulau M, McInnes-Clarke S (2017) Digital mapping of soil erodibility for water erosion in New South Wales, Australia. Soil Research 56, 158–170.
| Digital mapping of soil erodibility for water erosion in New South Wales, Australia.Crossref | GoogleScholarGoogle Scholar |
Yin S, Xie Y, Liu B, Nearing MA (2015) Rainfall erosivity estimation based on rainfall data collected over a range of temporal resolutions. Hydrology and Earth System Sciences 19, 4113–4126.
| Rainfall erosivity estimation based on rainfall data collected over a range of temporal resolutions.Crossref | GoogleScholarGoogle Scholar |
Yu BF, Rosewell C (2001) Evaluation of WEPP for runoff and soil loss prediction at Gunnedah, NSW, Australia. Australian Journal of Soil Research 39, 1131–1145.
| Evaluation of WEPP for runoff and soil loss prediction at Gunnedah, NSW, Australia.Crossref | GoogleScholarGoogle Scholar |