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Wildfire Effects on Permafrost and Soil Moisture in Spruce Forests of Interior Alaska
Christopher
Potter, NASA ARC, chris.potter@nasa.gov
(Presenter)
In the summer of 2015, hundreds of forest fires burned across the state of Alaska. Several uncontrolled wildfires near the town of Tanana on the Yukon River were responsible for the largest portion of the area burned statewide. In July 2017, field measurements were carried out in both unburned and burned forested areas nearly adjacent to one-another, all within 15 miles of the village of Tanana. These surveys were used to first visually verify locations of different burn severity class (low, moderate, or high) estimated in 2016 from Landsat images (collected before and after the 2015 Tanana-area wildfires). Surface and profile measurements to 30 cm depth of soil layers at these same locations were collected for evidence of moss layer and forest biomass burning. Soil temperature and moisture content was measured to 30 cm depth, and depth to permafrost was estimated by soil excavation, wherever necessary. Digital thermal infra-red (TIR) images of the soil profiles were taken at each site location, and root-zone organic layer samples were extracted for further chemical analysis. Results supported the hypothesis that the loss of surface organic layers is a major factor determining post-fire soil water and temperature changes and the depth of permafrost thawing. In the most severely burned forest sites, complete consumption of the living moss organic layer was strongly associated with both warming at the soil surface layer and increases in soil water content, relative to unburned forest sites. Soil temperature at both 10 cm and 30 cm depth at burned forest sites increased by 8 - 10 deg. C compared to unburned forest sites. Below 15 cm soil depth, the temperature of unburned sites dropped gradually to frozen levels by 30 cm depth, while soil temperatures at burned sites remained above 5o C to 30 cm depth. The water content measured at 3 cm depth at burned sites was commonly in excess of 30% by volume, compared to unburned forest sites. The strong correlation between burn index values and depth to permafrost measured across all forest sites sampled in July 2017 showed that the new ice-free profile in severely burned forest areas was commonly 50 cm deeper than in unburned forest soils. Associated Project(s): Poster Location ID: 8 Session Assigned: Carbon Dynamics
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