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Dissolved organic carbon lability increases with water residence time in the alluvial aquifer of a river floodplain ecosystem
Author(s) -
Helton Ashley M.,
Wright Meredith S.,
Bernhardt Emily S.,
Poole Geoffrey C.,
Cory Rose M.,
Stanford Jack A.
Publication year - 2015
Publication title -
journal of geophysical research: biogeosciences
Language(s) - English
Resource type - Journals
eISSN - 2169-8961
pISSN - 2169-8953
DOI - 10.1002/2014jg002832
Subject(s) - dissolved organic carbon , aquifer , lability , environmental chemistry , hydrology (agriculture) , hyporheic zone , environmental science , chemistry , groundwater , surface water , geology , environmental engineering , biochemistry , geotechnical engineering
We assessed spatial and temporal patterns of dissolved organic carbon (DOC) lability and composition throughout the alluvial aquifer of the 16 km 2 Nyack Floodplain in northwest Montana, USA. Water influx to the aquifer derives almost exclusively from the Middle Fork of the Flathead River, and water residence times within the aquifer range from days to months. Across seasons and channel discharge conditions, we measured DOC concentration, lability, and optical properties of aquifer water sampled from 12 wells, both near and ~3 m below the water table. Concentrations of DOC were typically low (542 ± 22.7 µg L −1 ; mean ± se), and the percentage of labile DOC averaged 18 ± 12% during 3 day laboratory assays. Parallel factor analysis of fluorescence excitation‐emission matrices revealed two humic‐like and two amino acid‐like fluorescence groups. Total DOC, humic‐like components, and specific UV absorbance decreased with water residence time, consistent with sorption to aquifer sediments. However, labile DOC (both concentration and fraction) increased with water residence time, suggesting a concurrent influx or production of labile DOC. Thus, although the carbon‐poor, oxygen‐rich aquifer is a net sink for DOC, recalcitrant DOC appears to be replaced with more labile DOC along aquifer flow paths. Our observation of DOC production in long flow paths contrasts with studies of hyporheic DOC consumption along short (centimeters to meters) flow paths and highlights the importance of understanding the role of labile organic matter production and/or influx in alluvial aquifer carbon cycling.

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