Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
International Journal of Wildland Fire International Journal of Wildland Fire Society
Journal of the International Association of Wildland Fire
RESEARCH ARTICLE

Testing and classification of individual plants for fire behaviour: plant selection for the wildland–urban interface

Robert H. White A and Wayne C. Zipperer B C
+ Author Affiliations
- Author Affiliations

A USDA, Forest Service, Forest Products Laboratory, One Gifford Pinchot Drive, Madison, WI 53726, USA. Email: rhwhite@fs.fed.us

B USDA Forest Service, PO Box 110806, Gainesville, FL 32611, USA.

C Corresponding author. Email: wzipperer@fs.fed.us

International Journal of Wildland Fire 19(2) 213-227 https://doi.org/10.1071/WF07128
Submitted: 29 August 2007  Accepted: 10 July 2008   Published: 31 March 2010

Abstract

Knowledge of how species differ in their flammability characteristics is needed to develop more reliable lists of plants recommended for landscaping homes in the wildland–urban interface (WUI). As indicated by conflicting advice in such lists, such characterisation is not without difficulties and disagreements. The flammability of vegetation is often described as having four components (ignitability, combustibility, sustainability and consumability). No standards or generally recognised test procedures exist for evaluating these components in plants. Some measurements of flammability include times for ignition, rate of flame spread, flame height and heat release rate. Often, the fire behaviour characteristics of a plant are derived from its physical and chemical characteristics. Thermogravimetric analysis and other thermal analyses of ground samples have long been used to characterise the thermal degradation of vegetation. More recently, researchers have used the oxygen consumption methodology to measure the heat released due to combustion of the vegetation. Although oxygen consumption calorimetry is an improvement in characterising plant flammability, translation of laboratory results to field conditions can be problematic and tests can be expensive.

Additional keywords: calorimetry, flammability, oxygen consumption, vegetation.


References


Albini FA (1980) Thermochemical properties of flame gases from fine wildland fuels. USDA Forest Service, Intermountain Forest and Range Research Station, Research Paper INT-243. (Ogden, UT)

Alessio GA, Peñuelas J, Llusià J, Ogaya R, Estiarte M , De Lillis M (2008) Influence of water and terpenes on flammability in some dominant Mediterranean species. International Journal of Wildland Fire  17, 274–286.
Crossref | GoogleScholarGoogle Scholar | CAS | Apte VB (Ed.) (2006) ‘Flammability testing of materials used in construction, transport and mining.’ (Woodhead Publishing Limited: Cambridge, UK)

Babrauskas V (1984) Development of the cone calorimeter – a bench scale heat release rate apparatus based on oxygen consumption. Fire and Materials  8, 81–95.
Crossref | GoogleScholarGoogle Scholar | CAS | Babrauskas V (2002a) The cone calorimeter. In ‘The SFPE handbook of fire protection engineering’. 3rd edn, pp. 3-63–3-81. (National Fire Protection Association: Quincy, MA)

Babrauskas V (2002b) Heat release rates. In ‘The SFPE handbook of fire protection and engineering’. 3rd edn, pp. 3-1–3-37. (National Fire Protection Association: Quincy, MA)

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

Babrauskas V (2006) Effective heat of combustion for flaming combustion of conifers. Canadian Journal of Forest Research  36, 659–663.
Crossref | GoogleScholarGoogle Scholar | Baker E, Woycheese JP (2007) Burning characteristics of Douglas-fir trees: scaling of individual tree fire based on tree size. In ‘Conference papers fire and materials, 2007, 10th international conference’, 29–31 January 2007, San Francisco, CA. (CD-ROM) (Interscience Communications: London)

Baptiste L (1992) ‘Firescape – landscaping to reduce fire hazard.’ (East Bay Municipal Utility District: Oakland, CA)

Beall FC (1969) Thermogravimetric analysis of wood lignin and hemicelluloses. Wood and Fiber  1, 215–226.
Beall FC, Eickner HW (1970) Thermal degradation of wood components: a review of the literature. USDA Forest Service, Forest Product Laboratory, Research Paper FPL 130. (Madison, WI)

Behm AL, Duryea ML, Long AJ , Zipperer WC (2004a) Flammability of native understory species in pine flatwood and hardwood hammock ecosystems and implications for the wildland–urban interface. International Journal of Wildland Fire  13, 355–365.
Crossref | GoogleScholarGoogle Scholar | Behm AL, Long AJ, Monroe MC, Randall CK, Zipperer WC, Hermansen-Baez LA (2004b) Fire in the wildland–urban interface: preparing a firewise plant list for WUI residents. University of Florida, Institute of Food and Agricultural Services, Florida Cooperative Extension Service Circular 1453. (Gainesville, FL)

Bilbao R, Mastral JF, Ceamanos J , Aldea ME (1996) Modeling of the pyrolysis of wet wood. Journal of Analytical and Applied Pyrolysis  36, 81–97.
Crossref | GoogleScholarGoogle Scholar | CAS | County of Los Angeles Fire Department (1998) Fuel modification guidelines for projects located in fire zone 4 or very high fire hazard severity. County of Los Angeles Fire Department, Prevention Bureau, Forestry Division, Brush Clearance Section. (Los Angeles, CA)

Damant GH , Nurbakhsh S (1994) Christmas trees – what happens when they ignite? Fire and Materials  18, 9–16.
Crossref | GoogleScholarGoogle Scholar | Detweiler AJ, Fitzgerald S (2006) Fire-resistant plants for home landscapes: selecting plants that may reduce your risk from wildfire. Oregon State University Extension Service, Pacific Northwest Extension (PNW) 590. (Corvallis, OR)

Dibble AC, White RH , Lebow PK (2007) Combustion characteristics of north-eastern USA vegetation tested in the cone calorimeter: invasive versus non-invasive plants. International Journal of Wildland Fire  16, 426–443.
Crossref | GoogleScholarGoogle Scholar | Doran JD, Randall CK, Long AJ (2004) Fire in the wildland–urban interface: selecting and maintaining firewise plants for landscaping. University of Florida, Institute of Food and Agricultural Services, Florida Cooperative Extension Service Circular 1445. (Gainesville, FL)

Emmons HW (1974) Fire and fire protection. Scientific American  231, 21–27.

Crossref | Enninful EK, Torvi DA (2005) Effects of moisture on smoke production and heat release rates of vegetation. In ‘Proceedings of The Combustion Institute, Canadian Section 2005 Spring Meeting’, 15–19 May 2005, Dalhousie University, Halifax, NS, Canada. (Eds P Amyotte, M Pegg) pp. 273–278. (The Combustion Institute, Canadian Section)

Etlinger MG , Beall FC (2004) Development of a laboratory protocol for fire performance of landscape plants. International Journal of Wildland Fire  13, 479–488.
Crossref | GoogleScholarGoogle Scholar | Evans DD, Rehm RG, Baker ES (2004) Physics-based modeling for WUI fire spread – simplified model algorithm for ignition of structures by burning vegetation. USDC National Institute of Standards and Technology NISTIR 7179. (Gaithersburg, MD)

Fernandes PM , Rego FC (1998) A new method to estimate fuel surface area-to-volume ratio using water immersion. International Journal of Wildland Fire  8, 121–128.
Crossref | GoogleScholarGoogle Scholar | Fogarty LG (2001) A flammability guide for some common New Zealand native tree and shrub species. Forest Research (Rotorua) in association with the New Zealand Fire Service Commission and National Rural Fire Authority, Forest Research Bulletin No. 197, Forest and Rural Fire Scientific and Technical Series, Report No. 6. (Wellington)

Fonda RW (2001) Burning characteristics of needles from eight pine species. Forest Science  47, 390–396.
Gill AM, Moore PHR (1996) Ignitibility of leaves of Australian plants. CSIRO Plant Industry, Centre for Plant Biodiversity Research. (Canberra)

Hough WA (1969) Caloric value of some forest fuels of the southern United States. USDA Forest Service, Southeastern Forest Experiment Station, Research Note SE-120. (Asheville, NC)

Huggett C (1980) Estimation of rate of heat release by means of oxygen consumption measurements. Fire and Materials  4, 61–65.
Crossref | GoogleScholarGoogle Scholar | CAS | Janssens M (2002) Calorimetry. In ‘The SFPE handbook of fire protection engineering’. 3rd edn, pp. 3-38–3-62. (National Fire Protection Association: Quincy, MA)

Liodakis S, Bakirtzis D , Lois E (2002) TG and autoignition studies on forest fuels. Journal of Thermal Analysis and Calorimetry  69, 519–528.
Crossref | GoogleScholarGoogle Scholar | CAS | Long A, Hinton B, Zipperer W, Hermansen-Baez A, Maranghides A, Mell W (2006) Quantifying and ranking the flammability of ornamental shrubs in the southern United States In ‘2006 Fire Ecology and Management Congress Proceedings. Quantifying and ranking the flammability of ornamental shrubs in the southern United States’. (DVD) (The Association for Fire Ecology and Washington State University Extension: San Diego, CA)

Lubin DM, Shelly JR (Eds) (1997) Defensible space landscaping in the urban/wildland interface: a compilation of fire performance ratings of residential landscape plants. University of California, Forest Products Laboratory, Internal Report No. 36.01.137. (Richmond, CA)

Lyon RE , Walters RN (2004) Pyrolysis combustion flow calorimetry. Journal of Analytical and Applied Pyrolysis  71, 27–46.
Crossref | GoogleScholarGoogle Scholar | CAS | Lyon RE, Walters RN (2007) Screening flame-retardants for plastics using microscale combustion calorimetry. In ‘Proceedings of the 18th annual conference on recent advances in flame retardancy of polymeric materials’, 21–23 May 2007, Stamford, CT. (Ed. M Lewin) Vol. 1, pp. 74–93. (BCC Research: Norwalk, CT)

Mak EHT (1988) Measuring foliar flammability with the limiting oxygen index method. Forest Science  34, 523–529.
Martin RE, Gordon DA, Gutierrez ME, Lee DS, Molina DM, Schroeder RA, Sapsis DB, Stephens SL, Chambers M (1994) Assessing the flammability of domestic and wildland vegetation. In ‘Proceedings of the 12th conference on fire and forest meteorology’, 26–28 October 1993, Jekyll Island, GA. pp. 130–137. (Society of American Foresters: Bethesda, MD)

Montgomery KR , Cheo PC (1971) Effect of leaf thickness on ignitibility. Forest Science  17, 475–478.
Orange County Fire Authority (2001) Guideline for fuel modification plans and maintenance program. Orange County Fire Authority, Guideline C-05 dated 10 April 2001. (Orange, CA)

Philpot CW (1969) Seasonal changes in heat content and ether extractive content of chamise. USDA Forest Service, Intermountain Forest and Range Experiment Station, Research Paper INT-61. (Ogden, UT)

Pyne SJ, Andrews PL, Laven RD (1996) ‘Introduction to Wildland Fire.’ 2nd edn. (Wiley: New York)

Radeloff VC, Hammer RB, Stewart SI, Fried JS, Holcomb SS , McKeefry JF (2005) The wildland–urban interface in the United States. Ecological Applications  15, 799–805.
Crossref | GoogleScholarGoogle Scholar | Rothermel RC (1972) A mathematical model for predicting fires spread in wildland fuels. USDA Forest Service, Intermountain Forest and Range Experiment Station, Research Paper INT-115. (Ogden, UT)

Sandberg DV, Ottmar RD , Cushon GH (2001) Characterizing fuels in the 21st century. International Journal of Wildland Fire  10, 381–387.
Crossref | GoogleScholarGoogle Scholar | Särdqvist S (1993) Initial fires – RHR, smoke production and CO generation from single items and room fire tests. Lund University, Institute of Technology, Department of Fire Safety Engineering. (Lund, Sweden)

Shafizadeh F, Chin PPS , DeGroot WF (1977) Effective heat content of green forest fuels. Forest Science  23, 81–89.
Stephens SL, Gordon DA, Martin RE (1994) Combustibility of selected domestic vegetation subjected to desiccation. In ‘Proceedings of the 12th Conference on Fire and Fire Meteorology’, 26–28 October 1993, Jekyll Island, GA. pp. 565–571. (Society of American Foresters: Bethesda, MD)

Stroup DW, DeLauter L, Lee J, Roadarmel G (1999) Scotch pine Christmas tree fire tests, Report of Test FR 4010. USDC, National Institute of Standards and Technology, 1 December 1999. (Gaithersburg, MD)

Sun L, Zhou X, Mahalingam S , Weise DR (2006) Comparison of burning characteristics of live and dead chaparral fuels. Combustion and Flame  144, 349–359.
Crossref | GoogleScholarGoogle Scholar | CAS | White RH, DeMars D, Bishop M (1997) Flammability of Christmas trees and other vegetation. In ‘Proceedings of the 24th international conference on fire safety’, 21–24 July 1997, Columbus, OH. (Ed. CJ Hilado) pp. 99–110. (Products Safety Corporation: Sissonville, WV)

White RH, Weise DR, Mackes K, Dibble AC (2002) Cone calorimeter testing of vegetation: an update. In ‘Proceedings of the 35th international conference on fire safety’, 22–24 July 2002, Columbus, OH. (Ed. CJ Hilado) pp. 1–12. (Products Safety Corporation: Sissonville, WV)

Williamson NM , Agee JK (2002) Heat content variation of interior Pacific Northwest conifer foliage. International Journal of Wildland Fire  11, 91–94.
Crossref | GoogleScholarGoogle Scholar |