Register      Login
International Journal of Wildland Fire International Journal of Wildland Fire Society
Journal of the International Association of Wildland Fire
RESEARCH ARTICLE

Measurement and prediction of post-fire erosion at the hillslope scale, Colorado Front Range

Juan de Dios Benavides-Solorio A and Lee H. MacDonald B C
+ Author Affiliations
- Author Affiliations

A INIFAP, Centro Regional de Investigación del Pacifico Centro, Parque Los Colomos s/n, Guadalajara, Jalisco 44660, Mexico. Telephone: +52 33 3641 2248; email: benavides.juandedios@inifap.gob.mx

B Department of Forest, Rangeland, and Watershed Stewardship, Colorado State University, Fort Collins, CO 80523-1472, USA.

C Corresponding author. Telephone: +1 970 491 6109; email: leemac@cnr.colostate.edu

International Journal of Wildland Fire 14(4) 457-474 https://doi.org/10.1071/WF05042
Submitted: 31 March 2005  Accepted: 28 June 2005   Published: 25 November 2005

Abstract

Post-fire soil erosion is of considerable concern because of the potential decline in site productivity and adverse effects on downstream resources. For the Colorado Front Range there is a paucity of post-fire erosion data and a corresponding lack of predictive models. This study measured hillslope-scale sediment production rates and site characteristics for three wild and three prescribed fires over two summers and one winter using 48 sediment fences. Over 90% of the sediment was generated by summer convective storms. Sediment production rates from recent, high-severity wildfires were 0.2–1.0 kg m–2 year–1. Mean sediment production rates from areas recently burned at moderate and low severity were only 0.02 and 0.005 kg m–2 year–1, respectively. For a given severity, sediment production rates from prescribed fires were generally lower than from wildfires, but there was considerable variability between plots and within fire severity classes. Fire severity, percent bare soil, rainfall erosivity, soil water repellency and soil texture explained 77% of the variability in sediment production rates, while a two-parameter model using percentage bare soil and rainfall erosivity explained 62% of the variability. Model validation confirmed the usefulness of these empirical models. The improved understanding of post-fire erosion rates can help guide forest management and post-fire rehabilitation efforts.

Additional keywords: fire severity; forests; models; rainfall erosivity; sediment production; surface cover.


References


Agnew W, Labn RE , Harding MV (1997) Buffalo Creek, Colorado, fire and flood of 1996. Land and Water  41, 27–29.
Benavides-Solorio JD (2003) Post-fire runoff and erosion at the plot and hillslope scale, Colorado Front Range. PhD Dissertation, Department of Earth Resources, Colorado State University, Fort Collins, CO.

Benavides-Solorio J , MacDonald LH (2001) Post-fire runoff and erosion from simulated rainfall on small plots, Colorado Front Range. Hydrological Processes  15, 2931–2952.
Crossref | GoogleScholarGoogle Scholar | Cambardella CA, Gajda AM, Doran JW, Wienhold BJ, Kettler TA (2001) Estimation of particulate and total organic matter by weight loss-on-ignition. In ‘Assessment methods for soil carbon’. (Eds R Lal, JM Kimble, RF Folletr, BA Stewart) pp. 349–359. (Lewis Publishers: Boca Raton, FL)

Campbell RE, Baker MB, Ffolliot PF, Larson FR, Avery CC (1977) ‘Wildfire effects on a ponderosa pine ecosystem: an Arizona case study.’ USDA Forest Service, Rocky Mountain Forest and Range Experiment Station Research Paper RM-191. (Fort Collins, CO)

DeBano LF (1981) ‘Water repellent soils: a state-of-the-art.’ USDA Forest Service, Pacific Southwest Forest and Range Experiment Station General Technical Report PSW-46. (Berkeley, CA)

DeBano LF, Ffolliot PT, Baker MBJr (1996) Fire severity effects on water resources. In ‘Effects of fire on Madrean Province ecosystems; a symposium proceedings’. (Coordinators PF Ffolliot, LF DeBano, MB Baker Jr, GJ Gottfried, G Solis-Garza, CB Edminster, DG Neary, LS Allen, RH Hamre) pp. 77–84. USDA Forest Service, Rocky Mountain Forest and Range Experiment Station General Technical Report RM-GTR-289. (Tucson, AZ)

DeCoursey DG, Shaake JCJr, Seely EH (1982) Stochastic models in hydrology. In ‘Hydrologic modeling of small watersheds’. (Eds CT Haan, HP Johnson, DL Brakensiek) pp. 19–78. (American Society of Agricultural Engineers: St Joseph, MI)

Doerr SH (1998) On standardizing the ‘Water Drop Penetration Time’ and the ‘Molarity of an Ethanol Droplet’ techniques to classify soil hydrophobicity: a case study using medium textured soils. Earth Surface Processes and Landforms  23, 663–668.
Crossref | GoogleScholarGoogle Scholar | Doesken NJ, Judson A (1997) ‘The snow booklet: a guide to the science, climatology, and measurement of snow in the United States.’ (Department of Atmospheric Science, Colorado State University: Fort Collins, CO)

Dunkerley DL , Brown KJ (1995) Runoff and runon areas in a patterned chenopod shrubland, arid western New South Wales, Australia – characteristics and origin. Journal of Arid Environments  30, 41–55.

Crossref | Evans R (1980) Mechanics of water erosion and their spatial and temporal controls: an empirical viewpoint. In ‘Soil erosion’. (Eds MJ Kirkby, PC Morgan) pp. 109–128. (John Wiley and Sons: Chichester)

Fox DM , Bryan RB (1999) The relationship of soil loss by inter-rill erosion to slope gradient. Catena  38, 211–222.
Crossref | GoogleScholarGoogle Scholar | Gary HL (1975) ‘Watershed management problems and opportunities for the Colorado Front Range ponderosa pine zone: The status of our knowledge.’ USDA Forest Service, Rocky Mountain Forest and Range Experiment Station Research Paper RM-139. (Fort Collins, CO)

Gary HL (1985) ‘A summary of research at the Manitou Experimental Forest in Colorado, 1937–1983.’ USDA Forest Service, Rocky Mountain Forest and Range Experiment Station General Technical Report RM-116. (Fort Collins, CO)

Gee GW, Bauder JW (1986) Particle-size analysis. In ‘Methods of soil analysis: Part 1’. (Ed. A Klute) pp. 383–411. (American Society of Agronomy: Madison, WI)

Graham RT (2003) ‘Hayman fire case study.’ USDA Forest Service, General Technical Report RMRS-GTR-114. (Ogden, UT)

Hendricks BA , Johnson JM (1944) Effects of fire on steep mountain slopes in central Arizona. Journal of Forestry  42, 568–571.
Huckaby LS, Kaufmann MR, Stoker JM, Fornwalt PJ (2001). Landscape patterns of montane forest age relative to fire history at Cheesman Lake in the Colorado Front Range. In ‘Ponderosa pine ecosystems restoration and conservation: steps toward stewardship’. (Compilers RK Vance, CB Edminster, WW Covington, JA Blake) pp. 19–27. USDA Forest Service, Rocky Mountain Research Station Proceedings RMRS-P-22. (Ogden, UT)

Inbar M, Tamir M , Wittenberg L (1998) Runoff and erosion processes after a forest fire in Mount Carmel, a Mediterranean area. Geomorphology  24, 17–33.
Crossref | GoogleScholarGoogle Scholar | Joyce LA, Birdsey R (Eds) (2000) ‘The impact of climate change on America’s forests: A technical document supporting the 2000 USDA Forest Service RPA Assessment.’ USDA Forest Service, Rocky Mountain Research Station General Technical Report RMRS-GTR-59. (Fort Collins, CO)

Kaufmann MR, Huckaby LS, Gleason P (2000a) Ponderosa pine in the Colorado Front Range: long historical fire and tree recruitment intervals and a case for landscape heterogeneity. In ‘Proceedings, Joint Fire Science Conference and Workshop, Vol. 1’. pp. 153–160. (Boise, ID)

Kaufmann MR, Regan CM , Brown PM (2000b) Heterogeneity in ponderosa pine/Douglas-fir forests: age and size structure in unlogged and logged landscapes of central Colorado. Canadian Journal of Forestry Research  30, 698–711.
Crossref | GoogleScholarGoogle Scholar | Kaufmann MR, Fornwalt PJ, Huckaby LS, Stoker JM (2001) Ponderosa pine forest reconstruction: comparisons with historical data. In ‘Ponderosa pine ecosystems restoration and conservation: steps toward stewardship’. (Compilers RK Vance, CB Edminster, WW Covington, JA Blake) pp. 9–18. USDA Forest Service, Rocky Mountain Research Station Proceedings RMRS-P-22. (Ogden, UT)

Keane RE, Ryan KC, Veblen TT, Allen CD, Logan J, Hawkes B (2002) ‘Cascading effects of fire exclusion in Rocky Mountain ecosystems: a literature review.’ USDA Forest Service, General Technical Report RMRS-GTR-91. (Fort Collins, CO)

Kilinc MY, Richardson EV (1973) ‘Mechanics of soil erosion from overland flow generated by simulated rainfall.’ Hydrology Paper #63. (Colorado State University: Fort Collins, CO)

Knighton AD (1998) ‘Fluvial forms and processes: a new perspective.’ (Arnold: London)

Libohova Z (2004) Effects of thinning and a wildfire on sediment production rates, channel morphology, and water quality in the Upper South Platte watershed. MS Thesis, Colorado State University, Fort Collins.

MacDonald LH , Huffman EL (2004) Post-fire soil water repellency: persistence and soil moisture threshold. Soil Science Society of America Journal  68, 1729–1734.
MacDonald LH, Stednick JD (2003) ‘Forests and water a state-of-the-art review for Colorado.’ Completion Report No. 196. (Colorado Water Resources Research Institute: Fort Collins)

Marcos E, Tarrega R , Luis-Calabuig E (2000) Comparative analysis of runoff and sediment yield with a rainfall simulator after experimental fire. Arid Soil Research and Rehabilitation  14, 293–307.
Crossref | GoogleScholarGoogle Scholar | McNabb DH, Swanson FJ (1990) Effects of fire on soil erosion. In ‘Natural and prescribed fire in Pacific Northwest forests’. (Eds JD Walstad, SR Radosevich, DV Sandberg) pp. 159–176. (Oregon State University Press: Corvallis)

Megahan WF, Molitor DC (1975) Erosional effects of wildfire and logging in Idaho. In ‘Watershed management symposium’. pp. 423–444. (Irrigation and Drainage Division, American Society of Civil Engineers: New York)

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.
Crossref | GoogleScholarGoogle Scholar | Miller JF, Frederick RH, Tracey RJ (1973) ‘Precipitation-frequency atlas of the Western United States; Volume III–Colorado.’ (National Oceanic and Atmospheric Administration, US Department of Commerce: Silver Spring, MD)

Moody JA , Martin DA (2001) Initial hydrologic and geomorphic response following a wildfire in the Colorado Front Range. Earth Surface Processes and Landforms  26, 1049–1070.
Crossref | GoogleScholarGoogle Scholar | Omi P (1994) ‘Hourglass Fire. Pingree Park vicinity. July 1–July 7, 1994.’ WESTFIRE, Department of Forest Sciences, Colorado State University. Available online at http://www.cnr.colostate.edu/frws/research/westfire/hourglass.htm [Verified 10 March 2005]

Osborn B (1953) Field measurements of soil splash to evaluate ground cover. Journal of Soil and Water Conservation  8, 255–266.
Ott LR, Longnecker M (2001) ‘An introduction to statistical methods and data analysis.’ 5th edn. (Duxbury: Pacific Grove, CA)

Pannkuk CD , Robichaud PR (2003) Effectiveness of needle cast at reducing erosion after forest fires. Water Resources Research  39, 1333.
Crossref | GoogleScholarGoogle Scholar | Renard KG, Foster GR, Weesies GA, McCool DK, Yoder DC (Coordinators) (1997) ‘Predicting soil erosion by water: a guide to conservation planning with the Revised Universal Soil Loss Equation (RUSLE).’ Agriculture Handbook No. 703. (US Department of Agriculture: Washington, DC)

Robichaud PR (2000) Fire effects on infiltration rates after prescribed fire in Northern Rocky Mountain forests, USA. Journal of Hydrology  231–232, 220–229.
Crossref | GoogleScholarGoogle Scholar | Robichaud PR, Brown RE (1999) What happened after the smoke cleared: onsite erosion rates after a wildfire in eastern Oregon. In ‘Proceedings of the American Water Resources Association on wildland hydrology’. (Eds D Olsen, JP Potyondy) pp. 419–426. (American Water Resources Association: Herndon, VA)

Robichaud PR, Brown RE (2002) ‘Silt fences: an economical technique for measuring hillslope erosion.’ USDA Forest Service, Rocky Mountain Research Station General Technical Report RM-GTR-94. (Fort Collins, CO)

Robichaud PR , Waldrop TA (1994) A comparison of surface runoff and sediment yields from low-and-high severity site preparation burns. Water Resources Bulletin  30, 27–34.
Robichaud PR, Beyers JL, Neary DG (2000) ‘Evaluating the effectiveness of postfire rehabilitation treatments.’ USDA Forest Service, Rocky Mountain Research Station General Technical Report RMRS-GTR-63. (Fort Collins, CO)

RSAC (2004) ‘Burned Area Emergency Rehabilitation (BAER) Imagery Support.’ Available online at http://www.fs.fed.us/eng/rsac/baer [Verified 5 November 2004]

Salas J, Smith F (1999) ‘Modeling watershed hydrology.’ Notes from CE/ER 524. (Colorado State University: Fort Collins, CO)

SAS Institute (1999) ‘The SAS system for Windows, release 8.01.’ (SAS: Cary, NC)

Scott HD (2000) ‘Soil physics, agricultural and environmental applications.’ (Iowa State University Press: Ames)

Singer MJ , Blackard J (1978) Effect of mulching on sediment in runoff from simulated rainfall. Soil Science Society of America Journal  4, 481–486.
Soil Survey Staff (1999) ‘Soil taxonomy. A basic system of soil classification for making and interpreting soil surveys.’ USDA Natural Resources Conservation Service, Agricultural Handbook No. 436. (US Department of Agriculture: Washington, DC)

Sorooshian S, Gupta VK (1995) Model calibration. In ‘Computer models of watershed hydrology’. (Ed. VP Singh) pp. 23–68. (Water Resources Publications: Highlands Ranch, CO)

Striffler WD, Mogren EW (1971) Erosion, soil properties and revegetation following a severe burn in the Colorado Rockies. In ‘Proceedings – Fire in the northern environment – a symposium’. (Eds CW Slaughter, J Barney, GM Hansen) pp. 25–36. (Pacific Northwest Forest and Range Experiment Station: Portland, OR)

Tran LT, Ridgley MA, Nearing MA, Kuckstein L, Sutherland R (2001) Using fuzzy logic-based modeling to improve the performance of the Revised Universal Soil Loss Equation. In ‘Sustaining the global farm. 10th International Soil Conservation Meeting, West Lafayette, IN’. (Eds DE Stoot, RH Moltar, GC Steinhardt) pp. 919–923. (International Soil Conservation Organization, US Department of Agriculture and Purdue University: West Lafayette, IN)

USDA Forest Service (1995) ‘Burned-area emergency rehabilitation handbook.’ USDA Forest Service Handbook 2509.13-95-7. (Washington, DC)

USDA Forest Service (2005) ‘A strategic assessment of forest biomass and fuel reduction treatments in Western States.’ USDA Forest Service General Technical Report RMRS-GTR-149. (Fort Collins, CO)

van Wagtendonk JW, Root RR , Key CH (2004) Comparison of AVIRIS and Landsat ETM+ detection capabilities for burn severity. Remote Sensing of Environment  92, 397–408.
Crossref | GoogleScholarGoogle Scholar | Wagenbrenner J (2003) Effectiveness of burned area emergency rehabilitation treatments, Colorado Front Range. MS Thesis, Colorado State University, Fort Collins.

Wells CG, Campbell RE, DeBano LF, Lewis CE, Fredriksen RL, Franklin EC, Froelich RC, Dunn PH (1979) ‘Effects of fire on soil, a state-of-knowledge review.’ USDA Forest Service, General Technical Report WO-7. (Washington, DC)

Willmott CJ, Ackelson SG, Davis RE, Feddema JJ, Klink KM, Legates DR, O’Donnell J , Rowe CM (1985) Statistics for the evaluation and comparison of models. Journal of Geophysical Research  90((C5)), 8995–9005.


Wright HA, Churchill FM , Stevens WC (1976) Soil loss, runoff, and water quality of seeded and unseeded steep watersheds following prescribed burning. Journal of Range Management  29, 294–298.


Yang D, Goodison BE, Metcalfe JR, Louie P , Leavesley G (1999) Quantification of precipitation measurement discontinuity induced by wind shields on national gauges. Water Resources Research  35, 491–508.

Crossref |