Foliar moisture content variations in lodgepole pine over the diurnal cycle during the red stage of mountain pine beetle attack

TitleFoliar moisture content variations in lodgepole pine over the diurnal cycle during the red stage of mountain pine beetle attack
Publication TypeJournal Article
Year of Publication2013
AuthorsPage, WG, Jenkins, MJ, Alexander, ME
JournalEnvironmental Modelling & Software
VolumeOn-line early
Start Page98
Issue49
Pagination5
Date Published08/2013
Keywordsbark beetle, crown fire, fine dead fuel moisture, insects and fire, technical reports and journal articles
Abstract

Widespread outbreaks of the mountain pine beetle (Dendroctonus ponderosae Hopkins) in the lodgepole pine (Pinus contorta Dougl. ex Loud. var. latifolia Engelm.) forests of North America have produced stands with significant levels of recent tree mortality. The needle foliage from recently attacked trees typically turns red within one to two years of attack indicating successful colonization by the beetle and tree death. Attempts to model crown fire potential in these stands have assumed that the moisture content of dead foliage responds similarly to changes in air temperature and relative humidity as other fine, dead surface fuels. However, this assumption has not been verified. In this exploratory study we sampled the moisture content of dead foliage on an hourly basis through two different diurnal cycles during the fire season and compared the results to measurements of 10-h fuel moisture indicator sticks and predictions made from models used to estimate dead fuel moisture in the USA, Canada, and Australia. The observed degree of variation in dead foliar moisture content was small (6.9e14.5%) with a mean value of w10%. All existing models performed poorly, but measurements of 10-h fuel moisture and a modified version of an existing model where timelags were extended to w20-h had the best fit to the data. The results from our study suggest that the dead foliage on attacked trees does not respond similarly to changing environmental conditions as other fine, dead surface fuels as has been assumed. This in turn has important implications for wildland fire suppression operations, including firefighter safety, and in modeling fire behavior, and solicits the need for further research.

DOI10.1016/j.envsoft.2013.08.001
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