Transpiration in recovering mixed loblolly pine and oak stands following wildfire in the Lost Pines region of Texas

Depending on severity, wildfire alters stand biomass, tree species distribution, and age, which may modify stand transpiration (Et) and the amount of water available to other parts of the hydrologic cycle. Our objective was to determine how wildfire severity affected Et in mixed pine/oak (Pinus taed...

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Bibliographic Details
Published inEcohydrology Vol. 12; no. 1
Main Authors Cooper, Caitlyn E., Aparecido, Luiza M.T., Muir, James P., Morgan, Cristine L.S., Heilman, James L., Moore, Georgianne W.
Format Journal Article
LanguageEnglish
Published Oxford Wiley Subscription Services, Inc 01.01.2019
Subjects
Age composition
Fires
Hydrologic cycle
Hydrological cycle
Hydrology
loblolly pine
Microclimate
Moisture content
Moisture stress
Oak
Pine
Pine trees
Pinus taeda
Quercus marilandica
Quercus stellata
regeneration
sap flux
Soil
Soil moisture
Transpiration
Vapor pressure
Vapour pressure
Water content
wildfire
Wildfires
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Summary:Depending on severity, wildfire alters stand biomass, tree species distribution, and age, which may modify stand transpiration (Et) and the amount of water available to other parts of the hydrologic cycle. Our objective was to determine how wildfire severity affected Et in mixed pine/oak (Pinus taeda L./Quercus stellata Wangehn., Quercus marilandica Muenchh.) stands in the Lost Pines eco‐region (Bastrop, TX, USA). Transpiration was estimated for mature pines and oaks at unburned and moderately burned sites and oak resprouts and pine saplings at a severely burned plot. On average, mature pines had 36% greater sap flux rates (Js) than mature oaks in the unburned and moderately burned stands. Under low moisture stress, regenerating pines had greater Js than resprouting oaks, but Js quickly decreased as soil moisture declined. By contrast, mature pines were unaffected by dry periods. Pines contributed most to Et at the unburned and moderate stands. Conversely, oak Et dominated the severely burned stand, contributing over 95%. Transpiration was greatest at the moderately burned stand (2.02 mm day−1), followed by the unburned (1.44 mm day−1), and the severely burned stands (0.46 mm day−1). Despite greater Js in resprouts and saplings, reductions in total sapwood area resulted in lower stand‐level daily Et at the severe site. Although severe fire decreased stand transpiration through reductions in vegetation density, individual oak resprouts appear to thrive, undeterred by high vapour pressure deficit. Without pine planting, oaks will likely dominate severely burned stands that could result in shifts to local hydrology and microclimate.
ISSN:1936-0584
1936-0592
DOI:10.1002/eco.2052