Cambial Phenology Informs Tree-Ring Analysis of Fire Seasonality in Coastal Plain Pine Savannas

Understanding of historical fire seasonality should facilitate development of concepts regarding fire as an ecological and evolutionary process. In tree-ring based fire-history studies, the seasonality of fire scars can be classified based on the position of the fire scar within or between growth ri...

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Published inFire ecology Vol. 14; no. 1; pp. 164 - 185
Main Authors Rother, Monica T., Huffman, Jean M., Harley, Grant L., Platt, William J., Jones, Neil, Robertson, Kevin M., Orzell, Steve L.
Format Journal Article
LanguageEnglish
Published Cham Springer International Publishing 01.02.2018
Springer Nature B.V
Subjects
Biomedical and Life Sciences
Coastal plains
Dendrochronology
Dormancy
Ecology
Growth rings
Indigenous species
Life Sciences
Lightning
Morphology
Phenology
Pine
Pine trees
Pinus elliottii
Pinus palustris
Research Article
Scars
Seasonal variations
Tree rings
Trees
cambial phenology
fire seasonality
fire scars
fire regimes
North American Coastal Plain
dendrometer bands
long-leaf pine
pine savannas
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Summary:Understanding of historical fire seasonality should facilitate development of concepts regarding fire as an ecological and evolutionary process. In tree-ring based fire-history studies, the seasonality of fire scars can be classified based on the position of the fire scar within or between growth rings. Cambial phenology studies are needed to precisely relate a fire-scar position to months within a year because the timing of dormancy, earlywood production, and latewood production varies by species and location. We examined cambial phenology patterns of longleaf pine ( Pinus palustris Mill.), slash pine (P. elliottii Engelm.), and South Florida slash pine ( P. densa [Little & K.W Dorman] Silba) at sites in southern Georgia and south-central and northern Florida, USA. We developed long-term (2.5 yr to 12 yr) datasets of monthly growth and dormancy and determined when trees transitioned from producing early-wood to producing latewood each year. Most trees were dormant for a period of 1 to 2 months in the winter and transitioned from earlywood to latewood in June. Given the annual growth ring morphology of the pines that we studied and the timing of the lightning-fire season in our study area, we propose a new classification system for assigning seasonality to fire scars found in the three native upland pine species that we studied. This new system, which we name the Coastal Plain Pine System, accounts for the large proportion of latewood typical of these pines and includes a position (the transition position) that corresponds with the time of year when lightning fires occur most frequently. Our findings demonstrate how cambial phenology data can improve interpretation of fire-scar data for determining historical fire seasonality.
ISSN:1933-9747
1933-9747
DOI:10.4996/fireecology.140116418