Register      Login
International Journal of Wildland Fire International Journal of Wildland Fire Society
Journal of the International Association of Wildland Fire
Shopping Cart: ( empty )
You are here: Home > Journals > WF > WF06005
RESEARCH ARTICLE
Contents Vol 16(1)

Factors affecting sustained smouldering in organic soils from pocosin and pond pine woodland wetlands*

James Reardon A B , Roger Hungerford A and Kevin Ryan A
+ Author Affiliations
- Author Affiliations

A Rocky Mountain Research Station, Fire Sciences Laboratory, 5775 Highway 10 West, Missoula, MT 59803, USA.

B Corresponding author. Email: jreardon@fs.fed.us

International Journal of Wildland Fire 16(1) 107-118 https://doi.org/10.1071/WF06005
Published: 20 February 2007

Abstract

The smouldering combustion of peat and muck soil plays an important role in the creation and maintenance of wetland communities. This experimental study was conducted to improve our understanding of how moisture and mineral content constrain smouldering in organic soil. Laboratory burning was conducted with root mat and muck soil samples from pocosin and pond pine woodland wetlands common on the North Carolina coastal plain. The results of laboratory and prescribed burning were compared. Laboratory results showed that moisture and mineral content influenced sustained smouldering in root mat soils. Predictions based on logistic regression analysis show that root mat soils with an average mineral content of 4.5% had an estimated 50% probability of sustained smouldering at a moisture content of 93%, whereas at moisture contents above 145% the estimated probability was less than 10%. The odds that root mat soil will sustain smouldering decrease by 19.3% for each 5% increase in moisture content. Root mat soils with an average mineral content of 5.5% and a moisture content of 93% had an estimated 61% probability of sustained smouldering. The odds that root mat soil will sustain smouldering combustion increased by 155.9% with each 1% increase in mineral content. Root mat and muck soils differ in physical and chemical characteristics expected to influence smouldering behaviour. The formation of muck soil has led to increases in density, smaller soil particle size, changes in water holding characteristics and increases in waxes, resins and bituminous compounds. Muck soil smouldered at higher moisture contents than root mat soil. Muck soil at a moisture content of 201% had an estimated 50% probability of sustained smouldering, whereas at moisture contents above 260% the estimated probability was less than 10%. The odds that muck soil will sustain smouldering combustion decrease by 17.2% with each 5% increase in moisture content. Ground fire in the prescribed burns stopped its vertical spread in organic soils at moisture contents consistent with logistic regression predictions developed from our laboratory results.


Acknowledgements

This work was accomplished with funding from Seymour Johnson Air Force Base, Goldsborough, NC, and the support of Buck Abrams, Byran Henderson and Scott Smith. The prescribed burns conducted on the Green Swamp Preserve were made possible by the Nature Conservancy, through efforts of Margit Bucher, assistant director of science and stewardship, and the North Carolina Department Forest Resources in Whiteville, NC through the efforts of Gary Curcio, Research Forester.


References


Adams WA (1973) The effect of organic matter content on the bulk and true densities of some uncultivated podzolic soils. Journal of Soil Science  24, 10–17.
Crossref | GoogleScholarGoogle Scholar | Artsybashev ES (1983) ‘Forest Fires and Their Control.’ (Amerind Publishing: New Delhi)

Babrauskas V (2003) ‘Ignition Handbook.’ (Fire Science Publishers, Fire Science and Technology: Issaquah, WA)

Badr A, Skaggs RW (1978) The effect of land development on the physical properties of some North Carolina organic soils. Paper 78-2537. Winter meeting of the American Society of Agricultural Engineers, Chicago, IL. (American Society of Agricultural Engineers: St Joseph, MI)

Bartlette R, Reardon J, Curcio G (2005) Methods for characterizing moisture regimes for assessing fuel availability in pocosin, sand hills and appalachian vegetation communities. In ‘EastFIRE Conference Proceedings’. 11–13 May 2005, George Mason University, Fairfax, Virginia, USA. Available at http://www.comet.ucar.edu/outreach/abstract_final/EastFIREConfProc/Abstracts/Session%201C%20PDF/1C_Bartlette.pdf [Verified 8 January 2007]

Boelter DH (1964) Water storage characteristics of several peats in situ. Soil Science Society of America Proceedings  28, 176–178.
Brown JK, Marsden MA, Ryan KC, Reinhardt ED (1985) Predicting duff and woody fuel consumed by prescribed fire in the Northern Rocky Mountains. US Department of Agriculture, Forest Service, Intermountain Forest and Range Experiment Station Research Paper INT-337. (Ogden, UT)

Brown JK, Reinhardt ED , Fisher WC (1991) Predicting duff and woody consumption in northern Idaho prescribed fires. Forest Science  37, 1550–1556.
Christensen N (1981) Fire regimes in southeastern ecosystems. In ‘Fire Regimes and Ecosystem Properties’. (Eds HA Mooney, TM Bonnicksen, N Christensen, JE Lotan, WA Reiners) pp. 112–136. USDA Forest Service, General Technical Report WO-26. (Washington, DC)

Christensen N, Burchell R, Liggett A, Simms E (1981) The structure and development of pocosin vegetation. In ‘Pocosin Wetlands: An integrated Analysis of Coastal Plain Freshwater Bogs in North Carolina’. (Ed. CJ Richardson) pp. 43–61. (Hutchinson Ross Publishing Company: Stroudsburg, PA)

Christensen NL, Wilbur RA, McLean JS (1988) Soil-vegetation correlations in the pocosins of Croatan National Forest, North Carolina. US Fish and Wildlife Service Biological Report 88(28).

Collins ME, Kuehl RJ (2001) Organic matter accumulation and organic soils In ‘Wetland Soils Genesis Hydrology, Landscapes and Classification’. (Eds JL Richardson, MJ Vepraskas) pp. 137–161. (Lewis Publishers, CRC Press LLC: Boca Raton, FL)

Dahl TE (1991) ‘Wetland Resources of the United States.’ (US Fish and Wildlife Service, National Wetland Inventory: St Petersburg, FL)

Dolman JD, Buol SW (1967) A Study of Organic Soils (Histisols) in the Tidewater Region of North Carolina. Technical Bulletin No. 181, North Carolina Agricultural Experiment Station. (North Carolina State University: Raleigh NC)

Frandsen WH (1987) The influence of moisture and mineral soil on the combustion limits of smoldering forest duff. Canadian Journal of Forest Research  17, 1540–1544.
Frost CC (2000) Studies in landscape fire ecology and presettlement vegetation of the southeastern United States. PhD Dissertation, University of North Carolina, Chapel Hill, NC.

Hartford RA (1989) Smoldering combustion limits in peat as influenced by moisture, mineral content and organic bulk density. In ‘Proceedings of the 10th Conference on Fire and Forest Meteorology Ottawa, Ontario’. (Eds DC Maciver, H Auld, R Whitewood) pp. 282–286. (Forestry Canada, Netawawa National Forestry Institute: Chalk River, ON)

Hawkes BC (1993) Factors that influence peat consumption under dependent burning conditions: a laboratory study. PhD Dissertation, University of Montana, Missoula, MT.

Herman SM, Phernetton RA, Carter A, Gooch T (1991) Fire and vegetation in peat-based marshes of the coastal plain: Examples from the Okefenokee and Great Dismal Swamp. In ‘Proceedings of the 17th Tall Timbers Fire Ecology Conference. High Intensity Fire in Wildlands: Management Challenges and Options’. pp. 217–234. (Tall Timbers Research Station: Tallahassee, FL)

Hosmer DW, Lemeshow S (1988) ‘Applied Logistic Regression.’ (Wiley Interscience, John Wiley & Sons: New York)

Huck RW, Rawlinson SE (1982) Peat resource inventory of South-Central Alaska, a data report. Alaska Open-File Report 150. (Alaska Department of Natural Resources: Anchorage, AK)

Hungerford RD, Frandsen WH, Ryan KC (1995) Ignition and burning characteristics of organic soils. In ‘Fire in Wetlands: A Management Perspective. Proceedings of the Tall Timbers Fire Ecology Conference no. 19’. (Eds SI Cerulean, RT Engstrom) pp. 78–91. (Tall Timbers Research Station: Tallahassee, FL)

Hungerford RD, Frandsen WH, Ryan KC (1996) Heat transfer into duff and organic soil. Final Project Report, FWS Agreement No. 14-48-009-962. USDA Forest Service, Intermountain Research Station. (Fire Sciences Laboratory: Missoula MT)

Ingram R (1987) Peat deposits of North Carolina. Bulletin 88, Department of Natural Resources and Community Development, Geologic Survey Section. (Raleigh, NC)

Kologiski RL (1977) The phytosociology of the Green Swamp, North Carolina. North Carolina, Agriculture Experiment Station Technical Bulletin No. 250. (North Carolina State University: Raleigh, NC)

Lilly JP (1981) The Blackland soils of North Carolina: their characteristics and management for agriculture. North Carolina, Agriculture Experiment Station Technical Bulletin No. 270. (North Carolina State University: Raleigh, NC)

McCarter RJ (1978) Smoldering combustion of wood fibers: cause and prevention. Journal of Fire and Flammability  9, 119–126.
McMahon CK, Wade DD, Tsoukalas SN (1980) Combustion characteristics and emissions from burning organic soils. In ‘Proceedings of the 73rd Annual Meeting of the Air Pollution Control Association’. Montreal, Quebec. (Air Pollution Control Association: Pittsburgh, PA)

Miyanishi K , Johnson EA (2002) Process and patterns of duff consumption in the mixed boreal forest. Canadian Journal of Forest Resources  32, 1285–1295.
Crossref | GoogleScholarGoogle Scholar | Ohlemiller TJ (1995) Smoldering combustion. In ‘SFPE Handbook of Fire Protection Engineering’. 2nd edn. (Eds PM DiNenno, D Drysdale, J Hall) pp. 171–179. (National Fire Protection Association: Quincy, MA)

Ohlemiller TJ, Bellan J , Rodgers F (1979) A model of smoldering combustion applied to flexible polyurethane foams. Combustion and Flame  36, 197–215.
Crossref | GoogleScholarGoogle Scholar | Ottmar RD, Vihnanek RE (2000) ‘Stereo Photo Series for Quantifying Natural Fuels. Volume VI: Longleaf, Pocosin and Marshgrass Types in the Southeastern United States.’ PMS 835. (National Wildfire Coordinating Group, National Interagency Fire Center: Boise ID)

Peter SP (1992) Heat transfer beneath a spreading fire. PhD Dissertation, The University of New Brunswick, Fredricton, New Brunswick.

Sandberg DV (1980) Duff reduction by prescribed underburning in Douglas-fir. USDA Forest Service, Pacific Northwest Forest and Range Experiment Station PNW-272. (Portland, OR)

Scott J (1999) Quantifying surface fuel characteristics in pocosin plant communities at the Dare County Bombing Range. Research Joint Venture Agreement INT-96093. (Intermountain Research Station, Fire Science Laboratory: Missoula, MT)

Skaggs RW, Gilliam JW , Evans RO (1991) A computer simulation study of pocosin hydrology wetlands. Journal of the Society of Wetland Scientists  11, 339–416.
Skopec RA (1983) Organic geochemisrty of the Alligator River Complex peat, North Carolina. MS Thesis, Kent State University, Kent, Ohio.

Sims AP, Niyogi DS , Raman S (2002) Adopting drought indices for estimating soil moisture: A North Carolina case study. Geophysical Research Letters  29, 1183.
Crossref | GoogleScholarGoogle Scholar | Tant PL (1992) ‘Soil survey of Dare County, North Carolina.’ (USDA Soil Conservation Service: Raleigh, NC)

Watts WA (1980) The Late Quaternary vegetation history of the southeastern United States. Annual Review of Ecology and Systematics  11, 387–409.
Crossref | GoogleScholarGoogle Scholar | Wein RW (1981) Fire behavior and ecological effects in organic terrain. In ‘SCOPE 18: The Role of Fire in Northern Circumpolar Ecosystems’. (Eds R Wein, D Maclean) pp. 81–95. (John Wiley & Sons: New York)

Wells BW , Boyce SG (1953) Carolina Bays: additional data on their origin age and history. Journal of Elisha Mitchell Science Society  69, 148–150.


Whitehead DR (1981) Late-Pleistocene vegetational changes in northeastern North Carolina. Ecological Monographs  51, 451–471.
Crossref | GoogleScholarGoogle Scholar |




* This article was written and prepared by US Government employees on official time and is therefore in the public domain and not subject to copyright.