Physiographic Controls and Wildfire Effects on Aquatic Biogeochemistry in Tundra of the Yukon‐Kuskokwim Delta, Alaska

Northern high‐latitude deltas are hotspots of biogeochemical processing, terrestrial‐aquatic connectivity, and, in Alaska's Yukon‐Kuskokwim Delta (YKD), tundra wildfire. Yet, wildfire effects on aquatic biogeochemistry remain understudied in northern delta regions, thus limiting a more comprehe...

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Bibliographic Details
Published in:Journal of geophysical research. Biogeosciences 2022-08, Vol.127 (8), p.n/a
Main Authors: Zolkos, Scott, MacDonald, Erin, Hung, Jacqueline K. Y., Schade, John D., Ludwig, Sarah, Mann, Paul J., Treharne, Rachael, Natali, Susan
Format: Article
Language:English
Subjects:
Aquatic ecosystems
Aquatic environment
Biogeochemical cycle
Biogeochemical cycles
Biogeochemistry
carbon
Carbon dioxide
Channels
Combustion
Conductance
Connectivity
Deltas
Dissolved organic carbon
Ecosystem recovery
Ecosystems
environmental change
Fens
Fires
Fresh water
Freshwater
Freshwater lakes
Hydrochemistry
Hydrology
Inland water environment
Lakes
Latitude
Linkages
Microorganisms
Nitrogen
northern
Nutrient cycles
nutrients
Organic matter
Organic soils
Peat
Permafrost
pH effects
Ponds
Recovery
Rivers
Soil organic matter
Solutes
Streams
Taiga & tundra
Terrain
Tundra
Variation
Water chemistry
Watersheds
Wildfires
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Summary:Northern high‐latitude deltas are hotspots of biogeochemical processing, terrestrial‐aquatic connectivity, and, in Alaska's Yukon‐Kuskokwim Delta (YKD), tundra wildfire. Yet, wildfire effects on aquatic biogeochemistry remain understudied in northern delta regions, thus limiting a more comprehensive understanding of high latitude biogeochemical cycles. In this study, we assess wildfire impacts on summertime aquatic biogeochemistry in YKD tundra using a multi‐year (2015–2019) data set of water chemistry measurements (n = 406) from five aquatic environments: peat plateau ponds, fen ponds, fen channels, lakes, and streams. We aimed to (a) characterize variation in hydrochemistry among aquatic environments; (b) determine wildfire effects on hydrochemistry; and (c) assess post‐fire multi‐year patterns in hydrochemistry in lakes (lower terrestrial‐freshwater connectivity) and fen ponds (higher connectivity). Variation in hydrochemistry among environments was more strongly associated with watershed characteristics (e.g., terrestrial‐aquatic connectivity) than wildfire. However, certain hydrochemical constituents showed consistent wildfire effects. Decreases in dissolved organic carbon (DOC) and CO2, and increases in pH, specific conductance, NH4+, and NO3− indicate that, by combusting soil organic matter, wildfire reduces organics available for hydrologic transport and microbial respiration, and mobilizes nitrogen into freshwaters. Multi‐year post‐fire variation in specific conductance, DOC, and CO2 in lakes and fen ponds suggest that watershed characteristics underlie ecosystem response and recovery to wildfire in the YKD. Together, these results indicate that increasing tundra wildfire occurrence at northern high latitudes could drive multi‐year shifts toward stronger aquatic inorganic nutrient cycling, and that variation in terrain characteristics is likely to underlie wildfire effects on aquatic ecosystems across broader scales. Plain Language Summary Warming at northern high latitudes is expected to increase wildfire activity, permafrost thaw, and hydrologic connectivity. Yet, contrasting evidence for wildfire effects on aquatic biogeochemistry hinders a more concrete understanding of potential future changes to northern ecosystems, especially in delta environments, where land‐freshwater linkages are strong. To address this, we made ∼400 measurements of hydrochemistry within the Yukon‐Kuskokwim Delta, Alaska, following high wildfire activity in 2015. Variati
ISSN:2169-8953
2169-8961
DOI:10.1029/2022JG006891