Emissions of volatile organic compounds from heated needles and twigs of Pinus pumila

Feng-jun Zhao , Li-fu Shu , Qiu-hua Wang , Ming-yu Wang , Xiao-rui Tian

Journal of Forestry Research ›› 2011, Vol. 22 ›› Issue (2)

PDF
Journal of Forestry Research ›› 2011, Vol. 22 ›› Issue (2) DOI: 10.1007/s11676-011-0157-9
Original Paper

Emissions of volatile organic compounds from heated needles and twigs of Pinus pumila

Author information +
History +
PDF

Abstract

A study was conducted to explore the mechanism that emissions of volatile organic compounds (VOC) from heated needles and twigs (200°C, within 15 min) of Pinus pumila affect fire behaviours using the technology of Thermal Desorption — Gas Chromatography — Mass Spectrometry (TD-GC-MS). The results indicated that the main components of VOC from heated needles and twigs are terpenoids. Most of these terpenoids are monoterpenes. Terpenoids account for 72.93% for the needles and 92.40% for the twigs of the total VOC, and their emission ratios are 61.200 μg·g−1 and 217.060 μg·g−1 respectively. Heated twigs can emit more terpenoids than heated needles because twigs had more volatile oils than needles. In actual fires, these large amounts of terpenoid emissions, especially the monoterpene emissions, have strong effects on fire behaviors that are not only in the initial stage but also in the fast propagation stage of fires. These flammable gases are capable of causing violent combustion and creating crown fires. In addition, if these gases accumulate in an uneven geographical area, there will be a possible for eruptive fires and/or fires flashover to occur.

Keywords

forest fire / Pinus pumila / volatile oil / volatile organic compounds (VOC) / terpenoids

Cite this article

Download citation ▾
Feng-jun Zhao, Li-fu Shu, Qiu-hua Wang, Ming-yu Wang, Xiao-rui Tian. Emissions of volatile organic compounds from heated needles and twigs of Pinus pumila. Journal of Forestry Research, 2011, 22(2): DOI:10.1007/s11676-011-0157-9

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Chen C., He Z., Chen D., Huang Y., Xie Jinsheng.. Studies on the fire-resistance of 37 species of coniferous and broadleaf trees and it’s appraisal. Scientia Silvae Sinicae, 1995, 31: 135-143.
[2]

Chetehouna K., Barboni T., Zarguili I., Leoni E., Simeoni A., Fernandez-Pello A.C.. Investigation on the emission of volatile organic compounds from heated vegetation and their potential to cause an accelerating forest fire. Combustion Science and Technology, 2009, 181: 1273-1288.

[3]

Du Y., Wang Lifu.. Forest fire cases in China. 2007, Beijing: China Forestry Publishing House
[4]

Fan Weicheng.. An Introduction to Fire Science. 1993, Hefei: Hubei Science and Technology Press, 156 162
[5]

Granström K.. Emission of monoterpenes and VOCs during drying of sawdust in a spouted bed. Forest Products Journal, 2003, 53: 48-56.
[6]

Greenberg J.P., Friedli H., Guenther A.B., Hanson D., Harley P., Karl T.. Volatile organic emissions from the distillation and pyrolysis of Vegetation. Atmospheric Chemistry and Physics, 2006, 6: 81-91.

[7]

Jiang Mengxia.. A study on the growth and distribution of Pinus pumila in Daxing’anling Mountains. Scientia Silvae Sinicae, 1982, 18: 203-205.
[8]

Jin Y., Wu J., Sun F., Deng W., Wang H., Sun Wencheng.. Terpene composition of needle oil from Pinus tabulae formis and the comparison with other two-needle pines. Journal of Beijing Forestry University, 1994, 16: 38-47.
[9]

Maleknia S.D., Bell T.L., Adams M.A.. Eucalypt smoke and wildfires: Temperature dependent emissions of biogenic volatile organic compounds. International Journal of Mass Spectrometry, 2009, 279: 126-133.

[10]

Maleknia S.D., Vail T.M., Cody R.B., Sparkman D.O., Bell T.L., Adams M.A.. Temperature-dependent release of volatile organic compounds of eucalypts by direct analysis in real time (DART) mass spectrometry. Rapid Communications in Mass Spectrometry, 2009, 23: 2241-2246.

[11]

Okitsu S.. Distribution and growth of Pinus pumila regel along the Larix Gmelinii Rupr. timberline ecotone of Mt. Dal’nyaya Ploskaya, central Kamchatka. Proceedings of the NIPR Symposium on Polar Biology, 1998, 11: 159-168.
[12]

Okuda M., Sumida A., Ishii H., Vetrova V.P., Hara T.. Establishment and growth pattern of Pinus pumila under a forest canopy in central Kamchatka. Ecology research, 2008, 23: 831-840.

[13]

Ormeño E., Céspedes B., Sánchez I.A., Velasco-García A., Moreno J.M., Fernandez C., Baldy V.. The relationship between terpenes and flammability of leaf litter. Forest Ecology and Management, 2009, 257: 471-482.

[14]

Owens M.K., Lin C.D., Taylor C.A., Whisenant S.G.. Seasonal patterns of plant flammability and monoterpenes content in Juniperus ashei. Journal of Chemical Ecology, 1998, 24: 2115-2129.

[15]

Pompe A., Vines R.G.. The influence of moisture on the combustion of leaves. Australian Forestry Journal, 1966, 30: 231-241.
[16]

Shan Y., Li H., Qi Qige.. Experimental analysis of the burning and physicochemical property of principal species in Daxing’an Mountain Heilongjiang province. Fire Safety Science, 2003, 12: 74-78.
[17]

Shu L., Tian X., Kou Jilie.. Studies on fire resistant tree species of Dagui Mountains, Guangxi Zhuang Autonomous Region. Scientia Silvae Sinicae, 1999, 35: 69-76.
[18]

Shu L., Wang M., Tian X., Li Z., Xiao Yongjun.. The fire environment mechanism of lightning fire formed for Daxing’an Mountains. Scientia Silvae Sinicae, 2003, 39: 94-99.
[19]

Wen D., Shu Lifu.. Theory of Forest Fire. 1999, Harbin: Northeast Forest University Press, 21 27
[20]

White C.S.. Monoterpenes—their effects on ecosystem nutrient cycling. Journal of Chemical Ecology, 1994, 20: 1381-1406.

[21]

Xu Huacheng.. China Daxing’anling Mountains Forests. 1998, Beijing: Science Press, 15 16
[22]

Zedler P.H.. Are some plants born to burn?. Trends in Ecology & Evolution, 1995, 10: 393-395.

[23]

Zhao J., Bai Y., Wang Z., Zhang Shuyu.. Studies on the emission rates of plants VOCs in China. China Environmental Science, 2004, 24: 654-657.
AI Summary AI Mindmap
PDF

129

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/