Estimating the heat transfer to an organic soil surface during crown fire
D. K. Thompson A B D , B. M. Wotton C and J. M. Waddington BA Natural Resources Canada, Canadian Forest Service, Northern Forestry Centre, Edmonton, AB, T6H 3S5, Canada.
B McMaster Centre for Climate Change, McMaster University, Hamilton, ON, L8S 4K1, Canada.
C Natural Resources Canada, Canadian Forest Service, Great Lakes Forestry Centre, Sault Ste. Marie, ON, P6A 2E5, Canada.
D Corresponding author. Email: danthomp@nrcan.gc.ca
International Journal of Wildland Fire 24(1) 120-129 https://doi.org/10.1071/WF12121
Submitted: 21 July 2012 Accepted: 6 September 2014 Published: 23 December 2014
Abstract
The Peatland Smouldering and Ignition (PSI) model was developed to quantify the heat transfer from a wildfire to an organic soil or moss surface in a Sphagnum–black spruce peatland. The Canadian Fire Behaviour Prediction system was used as a basis for the relationship between wind speed and rate of spread. Convection, conduction, and radiation processes were modelled before and during the arrival of the flaming front. The net heat flux to the soil from fire varied between 1.1 and 8.6 MJ m–2, with moderate-intensity fires transferring more energy to the surface compared with higher-intensity fires under higher winds. Radiative heat transfer to the soil surface both before the fire’s arrival and within the flaming front were the primary mechanisms of energy gain to the peatland surface. The role of convective and conductive cooling was no greater than 30% of gross energy gain. Peatland surface ignition in hummock and hollow microforms was modelled under normal and drought conditions. Hollow microforms dried out significantly during the course of a summer and increased their ignition vulnerability. Small-scale changes in slope and aspect of the peatland surface increased the amount of heat transferred by radiation by up to 30%, allowing some areas of higher soil moisture content to ignite. While no direct model validation is available, model outputs showing the preferential combustion of lichen and feathermoss, and the lack of ignition in Sphagnum in all but the most severe drought generally mimic observed ignitions patterns. The modelled peak of net energy input to the surface occurred at moderate wind speeds, suggesting that high-intensity fires do not necessarily lead to greater energy transfer and risk of smouldering combustion.
References
Àgueda A, Pastor E, Pérez Y, Planas E (2010) Experimental study of the emissivity of flames resulting from the combustion of forest fuels. International Journal of Thermal Sciences 49, 543–554.| Experimental study of the emissivity of flames resulting from the combustion of forest fuels.Crossref | GoogleScholarGoogle Scholar |
Albini FA (1985) A model for fire spread in wildland fuels by radiation. Combustion Science and Technology 42, 229–258.
| A model for fire spread in wildland fuels by radiation.Crossref | GoogleScholarGoogle Scholar |
Alexander ME, Stocks BJ, Lawson BD (1991) Fire behavior in black spruce–lichen woodland: the Porter Lake Project. Forestry Canada, Northern Forestry Centre, Information Report NOR–X–310 (Edmonton, AB).
Arora VK, Boer GJ (2005) Fire as an interactive component of dynamic vegetation models. Journal of Geophysical Research: Biogeosciences (2005–2012) 110,
| Fire as an interactive component of dynamic vegetation models.Crossref | GoogleScholarGoogle Scholar |
Benscoter BW, Wieder RK (2003) Variability in organic matter lost by combustion in a boreal bog during the 2001 Chisholm fire. Canadian Journal of Forest Research 33, 2509–2513.
| Variability in organic matter lost by combustion in a boreal bog during the 2001 Chisholm fire.Crossref | GoogleScholarGoogle Scholar |
Benscoter BW, Wieder RK, Vitt DH (2005) Linking microtopography with post-fire succession in bogs. Journal of Vegetation Science 16, 453–460.
| Linking microtopography with post-fire succession in bogs.Crossref | GoogleScholarGoogle Scholar |
Benscoter BW, Thompson DK, Waddington JM, Flannigan MD, Wotton BM, de Groot WG, Turetsky MR (2011) Interactive effects of vegetation, soil moisture, and bulk density on the depth of burning of thick organic soils. International Journal of Wildland Fire 20, 418–429.
| Interactive effects of vegetation, soil moisture, and bulk density on the depth of burning of thick organic soils.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3MXlsFGlsLo%3D&md5=673fa05971d5b03648118009bdaef5beCAS |
Bergman TL, Incropera FP, Lavine AS, DeWitt DP (2011) ‘Fundamentals of Heat and Mass Transfer.’ (Wiley: New York)
Butler BW, Finney MA, Andrews PL, Albini FA (2004) A radiation-driven model for crown fire spread. Canadian Journal of Forest Research 34, 1588–1599.
| A radiation-driven model for crown fire spread.Crossref | GoogleScholarGoogle Scholar |
Byram GM (1959) Combustion of forest fuels. In ‘Forest fire: control and use’. (Ed. KP Davis) pp. 61–68. (McGraw-Hill: New York)
Campbell GS, Jungbauer JD, Bidlake WR, Hungerford RD (1994) Predicting the effect of temperature on soil thermal conductivity. Soil Science 158, 307–313.
| Predicting the effect of temperature on soil thermal conductivity.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK2MXis1ans7k%3D&md5=f4ed5830445646ea7462fa77597c4f39CAS |
Campbell GS, Jungbauer JD, Bristow KL, Hungerford RD (1995) Soil temperature and water content beneath a surface fire. Soil Science 159, 363–374.
| Soil temperature and water content beneath a surface fire.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK2MXmsVOht7Y%3D&md5=63bad0db531490e3c3c746f9680b54b2CAS |
Cruz MG, Butler BW, Alexander ME, Forthofer JM, Wakimoto RH (2006) Predicting the ignition of crown fuels above a spreading fire surface. Part I: model realization. International Journal of Wildland Fire 15, 47–60.
| Predicting the ignition of crown fuels above a spreading fire surface. Part I: model realization.Crossref | GoogleScholarGoogle Scholar |
de Groot WJ, Pritchard JM, Lynham TJ (2009) Forest floor consumption and carbon emissions in Canadian boreal forest fires. Canadian Journal of Forest Research 39, 367–382.
| Forest floor consumption and carbon emissions in Canadian boreal forest fires.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1MXjtlyntbs%3D&md5=96228fea315f481beb8ba1d6cbe223a2CAS |
Drysdale D (2011) ‘An Introduction to Fire Dynamics.’ (Wiley: New York)
Dupuy J-L, Maréchal J (2011) Slope effect on laboratory fire spread: contribution of radiation and convection to fuel bed preheating. International Journal of Wildland Fire 20, 289–307.
| Slope effect on laboratory fire spread: contribution of radiation and convection to fuel bed preheating.Crossref | GoogleScholarGoogle Scholar |
Dupuy JL, Maréchal J, Morvan D (2003) Fires from a cylindrical forest fuel burner: combustion dynamics and flame properties. Combustion and Flame 135, 65–76.
| Fires from a cylindrical forest fuel burner: combustion dynamics and flame properties.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3sXnvVSjsbk%3D&md5=cde7a6f945aa9beeb3d5a5494717b189CAS |
Dupuy JL, Maréchal J, Portier D, Valette JC (2011) The effects of slope and fuel bed width on laboratory fire behaviour. International Journal of Wildland Fire 20, 288
| The effects of slope and fuel bed width on laboratory fire behaviour.Crossref | GoogleScholarGoogle Scholar |
Farouki OT (1986) ‘Thermal Properties of Soils.’ (Clausthal-Zellerfeld: Rockport, MA).
Forestry Canada Fire Danger Group (1992) Development and structure of the Canadian Forest Fire Behavior Prediction System. Information Report ST-X-3. (Forestry Canada: Ottawa, ON)
Hartford RA, Frandsen WH (1992) When it’s hot, it’s hot ... or maybe it’s not! (surface flaming may not portend extensive soil heating). International Journal of Wildland Fire 2, 139–144.
| When it’s hot, it’s hot ... or maybe it’s not! (surface flaming may not portend extensive soil heating).Crossref | GoogleScholarGoogle Scholar |
Hawkes BC (1993) Factors that influence peat consumption under dependent burning conditions: a laboratory study. PhD thesis, University of Montana, Missoula.
Johnson EA (1992) ‘Fire and Vegetation Dynamics: Studies from the North American Boreal Forest.’ (Cambridge University Press: Cambridge, UK)
Johnston DC (2012) Quantifying the fuel load, fuel structure and fire behaviour of forested bogs and blowdown. MSc thesis, University of Toronto, Canada.
Kettridge N, Baird AJ (2010) Simulating the thermal behavior of northern peatlands with a 3-D microtopography. Journal of Geophysical Research 115, G03009
| Simulating the thermal behavior of northern peatlands with a 3-D microtopography.Crossref | GoogleScholarGoogle Scholar |
Kettridge N, Thompson DK, Bombonato L, Turetsky MR, Benscoter BW, Waddington JM (2013) The ecohydrology of forested peatlands: simulating the effects of tree shading on moss evaporation and species composition. Journal of Geophysical Research: Biogeosciences 118, 422–435.
| The ecohydrology of forested peatlands: simulating the effects of tree shading on moss evaporation and species composition.Crossref | GoogleScholarGoogle Scholar |
Neary DG, Klopatek CC, DeBano LF, Ffolliott PF (1999) Fire effects on belowground sustainability: a review and synthesis. Forest Ecology and Management 122, 51–71.
| Fire effects on belowground sustainability: a review and synthesis.Crossref | GoogleScholarGoogle Scholar |
Ohlemiller TJ (1990) Smouldering combustion propagation through a permeable horizontal fuel layer. Combustion and Flame 81, 341–353.
| Smouldering combustion propagation through a permeable horizontal fuel layer.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK3cXlsFCmsb8%3D&md5=b7158b6b625fb356c7a68930f1ca3dd9CAS |
Oke TR (1987) ‘Boundary Layer Climates.’ (Routledge: New York)
Putnam AA (1965) A model study of wind-blown free-burning fires. In ‘Proceedings, 10th Symposium (International) on Combustion’, 17–21 August 1964, Cambridge, UK, pp. 1039–1056 (Combustion Institute: Pittsburgh, PA)
R Core Team (2013) R: A language and environment for statistical computing. (R Foundation for Statistical Computing: Vienna)
Rein G, Cleaver N, Ashton C, Pironi P, Torero JL (2008) The severity of smouldering peat fires and damage to the forest soil. Catena 74, 304–309.
| The severity of smouldering peat fires and damage to the forest soil.Crossref | GoogleScholarGoogle Scholar |
Rice SK, Aclander L, Hanson DT (2008) Do bryophyte shoot systems function like vascular plant leaves or canopies? Functional trait relationships in Sphagnum mosses (Sphagnaceae). American Journal of Botany 95, 1366–1374.
| Do bryophyte shoot systems function like vascular plant leaves or canopies? Functional trait relationships in Sphagnum mosses (Sphagnaceae).Crossref | GoogleScholarGoogle Scholar | 21628145PubMed |
Rydin H (1985) Effect of water table on dessication of Sphagnum in relation to surrounding Sphagna. Oikos 45, 374–379.
| Effect of water table on dessication of Sphagnum in relation to surrounding Sphagna.Crossref | GoogleScholarGoogle Scholar |
Shetler G, Turetsky MR, Kane E, Kasischke E (2008) Sphagnum mosses limit total carbon consumption during fire in Alaskan black spruce forests. Canadian Journal of Forest Research 38, 2328–2336.
| Sphagnum mosses limit total carbon consumption during fire in Alaskan black spruce forests.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1cXptFynt7o%3D&md5=6faee16de994e994b9dccbe605ec1825CAS |
Siegel R, Howell JR (2001) ‘Thermal Radiation Heat Transfer.’ (Taylor and Francis: Hemisphere, WA)
Tarnocai C, Kettles IM, Lacelle B (2011) Peatlands of Canada. Geological Survey of Canada, Open File 6551. (Natural Resources Canada: Ottawa, ON)
Taylor SW, Wotton BM, Alexander ME, Dalrymple GN (2004) Variation in wind and crown fire behaviour in a northern jack pine black spruce forest. Canadian Journal of Forest Research 34, 1561–1576.
| Variation in wind and crown fire behaviour in a northern jack pine black spruce forest.Crossref | GoogleScholarGoogle Scholar |
Thompson DK, Waddington JM (2013) Peat properties and water retention in boreal forested peatlands subject to wildfire disturbance. Water Resources Research 49, 3651–3658.
| Peat properties and water retention in boreal forested peatlands subject to wildfire disturbance.Crossref | GoogleScholarGoogle Scholar |
Thompson DK, Benscoter BW, Waddington JM (2013) Water balance of a burned and unburned forested boreal peatland. Hydrological Processes
| Water balance of a burned and unburned forested boreal peatland.Crossref | GoogleScholarGoogle Scholar |
Turetsky MR, Amiro BD, Bosch EM, Bhatti JS (2004) Historical burn area in western Canadian peatlands and its relationship to fire weather indices. Global Biogeochemical Cycles 18, GB4014
| Historical burn area in western Canadian peatlands and its relationship to fire weather indices.Crossref | GoogleScholarGoogle Scholar |
Usup A, Hashimoto Y, Takahashi H, Hayasaka H (2004) Combustion and thermal characteristics of peat fire in tropical peatland in Central Kalimantan, Indonesia. Tropics 14, 1–19.
| Combustion and thermal characteristics of peat fire in tropical peatland in Central Kalimantan, Indonesia.Crossref | GoogleScholarGoogle Scholar |
Van Wagner CE (1972) Duff consumption by fire in eastern pine stands. Canadian Journal of Forest Research 2, 34–39.
| Duff consumption by fire in eastern pine stands.Crossref | GoogleScholarGoogle Scholar |
Van Wagner CE (1977) Conditions for the start and spread of crown fire. Canadian Journal of Forest Research 7, 23–34.
| Conditions for the start and spread of crown fire.Crossref | GoogleScholarGoogle Scholar |
Van Wagner CE (1987) Development and structure of the Canadian Forest Fire Weather Index System. Canadian Forest Service, Technical Report 35 (Ottawa, ON).
Varner JM (2005) ‘Smoldering fire in long-unburned longleaf pine forests: linking fuels with fire effects.’ (University of Florida: Gainsville, FL).
Watts AC (2013) Organic soil combustion in cypress swamps: moisture effects and landscape implications for carbon release. Forest Ecology and Management 294, 178–187.
| Organic soil combustion in cypress swamps: moisture effects and landscape implications for carbon release.Crossref | GoogleScholarGoogle Scholar |
Weber RO (1989) Analytical models for fire spread due to radiation. Combustion and Flame 78, 398–408.
| Analytical models for fire spread due to radiation.Crossref | GoogleScholarGoogle Scholar |
Wieder RK, Scott KD, Kamminga K, Vile MA, Vitt DH, Bone T, Xu B, Benscoter BW, Bhatti JS (2009) Postfire carbon balance in boreal bogs of Alberta, Canada. Global Change Biology 15, 63–81.
| Postfire carbon balance in boreal bogs of Alberta, Canada.Crossref | GoogleScholarGoogle Scholar |
Williams TG, Flanagan LB (1996) Effect of changes in water content on photosynthesis, transpiration and discrimination against 13CO2 and C18O16O in Pleurozium and Sphagnum. Oecologia 108, 38–46.
| Effect of changes in water content on photosynthesis, transpiration and discrimination against 13CO2 and C18O16O in Pleurozium and Sphagnum.Crossref | GoogleScholarGoogle Scholar |
Zoltai SC, Morissey LA, Livingston GP, de Groot WJ (1998) Effects of fires on carbon cycling in North American boreal peatlands. Environmental Reviews 6, 13–24.
| Effects of fires on carbon cycling in North American boreal peatlands.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK1cXlsV2jt78%3D&md5=878dcd8045425e083e05c87139d8d1c1CAS |