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 > WF05055
RESEARCH ARTICLE
Contents Vol 15(2)

Combustion properties of Bromus tectorum L.: influence of ecotype and growth under four CO2 concentrations

Robert R. Blank A D , Robert H. White B and Lewis H. Ziska C
+ Author Affiliations
- Author Affiliations

A USDA Agricultural Research Service, Exotic and Invasive Weed Research Unit, 920 Valley Road, Reno, NV 89512, USA.

B USDA Forest Service, Forest Products Laboratory, One Gifford Pinchot Drive, Madison, WI 53726-2398, USA.

C Alternate Crops and Systems Lab, USDA Agricultural Research Service, Beltsville, MD 20705, USA.

D Corresponding author. Email: blank@unr.nevada.edu

International Journal of Wildland Fire 15(2) 227-236 https://doi.org/10.1071/WF05055
Submitted: 19 May 2005  Accepted: 1 December 2005   Published: 31 May 2006

Abstract

We grew from seed the exotic invasive annual grass Bromus tectorum L., collected from three elevation ecotypes in northern Nevada, USA. Plants were exposed to four CO2 atmosphere concentrations: 270, 320, 370, and 420 μmol mol–1. After harvest on day 87, above-ground tissue was milled, conditioned to 30% relative humidity, and combustion properties were measured using a cone calorimeter. Plants exposed to 270 μmol mol–1 CO2 had significantly less total heat released than plants exposed to higher CO2 concentrations. Total heat released was least for the low-elevation ecotype, statistically similar for the mid-elevation ecotype, and significantly increased for the high-elevation ecotype. Plant attributes that significantly correlated with heat release included tissue concentrations of lignin, glucan, xylan, potassium, calcium, and manganese. The data suggest that a decline in tissue concentrations of lignin, xylan, and mineral constituents, as CO2 concentration increases from 270 μmol mol–1 to higher levels, affects the combustion process. We suspect that as tissue concentrations of lignin and inorganics decline, char formation decreases, thereby allowing more complete combustion. Changes in combustion parameters of B. tectorum induced by different CO2 concentrations and elevation ecotype may be a strong consideration to understanding fire behaviors of the past, present, and future.

Additional keywords: char; flammability; global change; lignin; wildfire.


References


Allen LH, Vu JCV, Valle RR, Boote KJ , Jones PHD (1988) Nocturnal carbohydrates and nitrogen of soybean grown under carbon dioxide enrichment. Crop Science  28, 84–94.
ASTM International (2004) ‘Standard test method for heat and visible smoke release rates for materials and products using an oxygen consumption calorimeter. Designation: E 1354.’ (ASTM International: West Conshohocken, PA)

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 | Babrauskas V (2002) Chapter 3-3: The cone calorimeter. In ‘The SFPE handbook of fire protection engineering’. 3rd edn. (Eds PJ DiNenno, WD Walton) pp. 3-63–3-81. (National Fire Protection Association: Quincy, MA)

Baker AJ (1983) Wood fuel properties and fuel products from woods. In ‘Proceedings of fuel wood management and utilization seminar’. 9–11 November 1992. pp. 14–25. (Michigan State University: East Lansing, MI)

Brown JK (1970a) Ratios of surface area to volume for common fine fuels. Forest Science  16, 101–105.
Brown JK (1970b) ‘Physical fuel properties of ponderosa pine forest floors and cheatgrass.’ USDA Forest Service, Intermountain Forest and Range Experiment Station Research Paper INT-74. (Ogden, UT)

Browne FL (1958) ‘Theories of the combustion of wood and its control – A survey of the literature.’ USDA Forest Service, Forest Products Laboratory FPL Report No. 2136. (Madison, WI) Available at http://www.fpl.fs.fed.us/documnts/fplmisc/rpt2136.pdf [Verified 7 April 2006]

Campbell CR, Plank CO (1998) Preparation of plant tissue for laboratory analysis. In ‘Handbook of reference methods for plant analysis’. (Ed. YP Kalra) pp. 37–49. (CRC Press: Boca Raton, FL)

Carty P , White S (1994) Flame retardancy and smoke suppression in a tertiary polymer blend. Polymer Degradation and Stability  44, 93–97.
Crossref | GoogleScholarGoogle Scholar | Janssens M (2002) Chapter 3-2: Calorimetry. In ‘The SFPE handbook of fire protection engineering’. 3rd edn. (Eds PJ DiNenno, WD Walton) pp. 3-38–3-62. (National Fire Protection Association: Quincy, MA)

Lincoln DE, Couvet D , Sionit N (1986) Response of an insect herbivory to host plants grown in carbon dioxide enriched atmospheres. Oecologia  69, 556–560.
Crossref | GoogleScholarGoogle Scholar | Lobert JM, Warnatz J (1993). Emissions from the combustion process in vegetation. In ‘Fire and the environment, the ecological atmospheric, and climatic importance of vegetation fires’. (Eds PJ Crutzen, JG Goldammer) pp. 15–38. (John Wiley and Sons: Chichester)

Mack RN (1981) Invasion of Bromus tectorum L. into western North America: an ecological chronicle. Agro-Ecosystems  7, 145–165.
Crossref | GoogleScholarGoogle Scholar | Mayeux HS, Johnson HB, Polley HW (1994) Potential interactions between global change and intermountain annual grassland. In ‘Ecology and management of annual rangeland’. (Eds SB Monson, SG Kitchen) pp. 95–100. USDA Forest Service, Intermountain Research Station General Technical Report INT-GTR-313. (Ogden, UT)

Norton LR, Firbank LG , Watkinson AR (1995) Ecotypic differentiation of response to enhanced CO2 and temperature levels in Arabidopsis thaliana. Oecologia  104, 394–396.
Crossref | GoogleScholarGoogle Scholar | Pellant M (1990) The cheatgrass–wildfire cycle – are there any solutions? In ‘Proceedings – symposium on cheatgrass invasion, shrub die-off, and other aspects of shrub biology and management’. (Eds ED McArthur, EM Romney, SD Smith, PT Tueller) pp. 11–18. USDA Forest Service, Intermountain Research Station General Technical Report INT-276. (Ogden, UT)

Philpot CW (1970) Influence of mineral content on the pyrolysis of plant materials. Forest Science  16, 461–471.
Rundel PW (1981) Structural and chemical components of flammability. In ‘Proceedings of the conference on fire regimes and ecosystem properties’. (Eds HA Mooney, TM Bonnicksen, N Christensen, JE Lotand, WA Reiners) pp. 183–207. USDA Forest Service, General Technical Report WO-26. (Washington, DC)

Sage EF (1996) Modification of fire disturbance by elevated CO2. In ‘Carbon dioxide, populations, and communities’. (Eds C Korner, FA Bazzaz) pp. 231–249. (Academic Press: San Diego, CA)

Schenk UJ, Jäger J , Weigel HJ (1997) The response of perennial ryegrass/white clover mini-swards to elevated atmospheric CO2 concentrations: effects on yield and fodder quality. Grass and Forage Science  52, 232–241.
Crossref | GoogleScholarGoogle Scholar | Shafizadeh F (1981) Basic principles of direct combustion. In ‘Biomass conversion processes for energy and fuels’. (Eds SS Sofer, OR Zaborsky) pp. 103–124. (Plenum Publishing: New York)

Statview (1998) ‘Statview reference.’ (SAS Institute: Cary, NC)

Tillman DA (1978) ‘Wood as an energy resource.’ (Academic Press: New York)

Tuchman NC, Wahtera KA, Wetzel RG , Teeri JA (2003) Elevated atmospheric CO2 alters leaf litter quality for stream ecosystems: An in situ leaf decomposition study: Decomposition of elevated CO2-altered leaf litter. Hydrobiologia  495, 203–211.
Crossref | GoogleScholarGoogle Scholar | White RH (1987) Effect of lignin content and extractives on the higher heating value of wood. Wood and Fiber Science 19, 446–452. Available at http://www.fpl.fs.fed.us/documnts/pdf1987/white87a.pdf [Verified 7 April 2006]

White RH, Weise DR, Mackes K, Dibble AC (2002) Cone calorimeter testing of vegetation – an update. In ‘35th international conference on fire safety’, July 2002, Ramada Plaza Hotel and Conference Center, Columbus, Ohio. pp. 1–12. (Product Safety Corporation: Sissonville, WV) Available at http://www.fpl.fs.fed.us/documnts/pdf2002/white02b.pdf [Verified 7 April 2006]

Young JA , Evans RA (1973) Downy brome – intruder in the plant succession of big sagebrush communities in the Great Basin. Journal of Range Management  26, 410–415.
Young JA, Tipton F (1990) Invasion of cheatgrass into arid environments of the Lahontan Basin. In ‘Proceedings – symposium on cheatgrass invasion, shrub die-off, and other aspects of shrub biology and management’. (Eds ED McArthur, EM Romney, SD Smith, PT Tueller) pp. 37–40. USDA Forest Service, Intermountain Research Station General Technical Report INT-276. (Ogden, UT)

Ziska LH, Ghannoum O, Baker JT, Conroy J, Bunce JA, Kobayashi K , Okada M (2001) A global perspective of ground level ‘ambient’ carbon dioxide for assessing the response of plants to atmospheric CO2. Global Change Biology  7, 789–796.
Crossref | GoogleScholarGoogle Scholar |

Ziska LH, Reeves J , Blank B (2005) The impact of recent increases in atmospheric CO2 on biomass production and vegetative retention of Cheatgrass (Bromus tectorum): implications for fire disturbance. Global Change Biology  11, 1325–1332.
Crossref | GoogleScholarGoogle Scholar |