Biogenic volatile organic compounds emissions at high temperatures of common plants from Mediterranean regions affected by forest fires

Vegetal species emit biogenic volatile organic compounds at elevated temperatures. Because of their combustibility, biogenic volatile organic compounds can modify the wildland fires propagation dynamics, changing them from a moderate behavior to an explosive propagation. This phenomenon is known as...

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Bibliographic Details
Published in:Journal of fire sciences 2014-09, Vol.32 (5), p.459-479
Main Authors: Courty, Léo, Chetehouna, Khaled, Lemée, Laurent, Fernandez-Pello, Carlos, Garo, Jean-Pierre
Format: Article
Language:English
Subjects:
Catalysis
Chemical Sciences
Cistus
Combustion
Devices
Fires
Forest fires
Lavandula
Organic compounds
Plants (organisms)
Thermal properties
Thymol
Thymus vulgaris
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Summary:Vegetal species emit biogenic volatile organic compounds at elevated temperatures. Because of their combustibility, biogenic volatile organic compounds can modify the wildland fires propagation dynamics, changing them from a moderate behavior to an explosive propagation. This phenomenon is known as an accelerating forest fire. The origin of such phenomena can be the accumulation of biogenic volatile organic compounds in concentrations close to their lower flammability limit in seasons where the plants are themselves very flammable. There is a lack of information on the biogenic volatile organic compounds emissions of vegetal species typically found in wildland fires at temperatures higher than ambient temperature. In this work, we used a flash pyrolysis device linked to a gas chromatograph/mass spectrometer to investigate experimentally the biogenic volatile organic compounds emissions of Thymus vulgaris, Lavandula stœchas, and Cistus albidus between 70°C and 180°C. High amounts of terpenoid compounds were found, except for C. albidus emissions, including thymol, l-fenchone, and 3-hexen-1-ol. The information provided in this work could help to improve the characterization of thermal degradation of vegetal fuels and to incorporate the biogenic volatile organic compounds combustion in physical forest fires models. They also show that under the right circumstances, biogenic volatile organic compounds from these vegetal species could contribute to the development of an accelerating forest fire.
ISSN:0734-9041
1530-8049
DOI:10.1177/0734904114536128