Organic matter compositions of rivers draining into Hudson Bay: Present-day trends and potential as recorders of future climate change

Godin, Pamela; Macdonald, Robie W.; Kuzyk, Zou Zou A.; Goñi, Miguel A.; Stern, Gary A.

doi:10.1002/2016jg003569

Cited by 29 publications

(29 citation statements)

References 85 publications

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“…This would be in line with Godin et al. (2017), Kalbitz et al. (2000), and Raymond and Hopkinson (2003) who also found that DOM contains mainly young components by 14 C dating.…”

Section: Discussionsupporting

confidence: 89%

“…The dating of the DOM in the various ecosystem solutions supports our hypothesis that DOM in rainfall originated from fresh plant tissue in the forest canopies and in the mineral soil solutions from canopy leachates, aboveground and belowground litter, or root exudates. This would be in line with Godin et al (2017), , and Raymond and Hopkinson (2003) who also found that DOM contains mainly young components by 14 C dating.…”

Section: Sources and Age Of Domsupporting

confidence: 89%

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Total organic carbon concentrations in ecosystem solutions of a remote tropical montane forest respond to global environmental change

Wilcke

Velescu

Leimer

et al. 2020

Global Change Biology

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“…This would be in line with Godin et al. (2017), Kalbitz et al. (2000), and Raymond and Hopkinson (2003) who also found that DOM contains mainly young components by 14 C dating.…”

Section: Discussionsupporting

confidence: 89%

Section: Sources and Age Of Domsupporting

confidence: 89%

Total organic carbon concentrations in ecosystem solutions of a remote tropical montane forest respond to global environmental change

Wilcke

Velescu

Leimer

et al. 2020

Global Change Biology

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“…The compositional lignin phenol parameters S/V, and C/V ranged from 0.32 to 0.48, and 0.06 to 0.13, respectively, and did not exhibit substantial changes with locations and time ( Table 1 and Figure 4). S/V and C/V are generally employed to explore sources of tDOC (i.e., angiosperm versus gymnosperm and woody versus nonwoody) (Hedges and Mann, 1979;Goñi and Hedges, 1995;Godin et al, 2017). Representative tissues and their leachates were integrated in Figure 4 to aid with identification of tDOC sources ( Supplementary Table S1).…”

Section: Concentrations and Distributions Of Doc And Biochemicalsmentioning

confidence: 99%

Hurricanes Accelerate Dissolved Organic Carbon Cycling in Coastal Ecosystems

et al. 2020

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Extreme weather events such as tropical storms and hurricanes deliver large amounts of freshwater (stormwater and river discharge) and associated dissolved organic carbon (DOC) to estuaries and the coastal ocean, affecting water quality, and carbon budgets. Hurricane Harvey produced an unprecedented 1000-year flood event in 2017 that inundated the heavily urbanized and industrialized Houston/Galveston region (TX, United States). Within a week, storm-associated floodwater delivered 87 ± 18 Gg of terrigenous dissolved organic carbon (tDOC) to Galveston Bay and the Gulf of Mexico continental shelves. In situ decay constants of 8. 75-28.33 year −1 resulted in the biomineralization of ∼70% of tDOC within 1 month of discharge from the flood plain. The high removal efficiency of tDOC was linked to a diverse microbial community capable of degrading a wide repertoire of dissolved organic matter (DOM), and suggested hurricane-induced flood events affect net CO 2 exchange and nutrient budgets in estuarine watersheds and coastal seas.

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“…As a result, these large systems are unlikely to be representative of the distributed array of smaller watersheds that comprise a significant proportion of the Arctic basin. Measurements characterizing the biogeochemistry of smaller rivers in Alaska (Townsend‐Small et al, ), Siberia (Johnston et al, ), around Hudson Bay (Godin et al, ), and in the Canadian Arctic Archipelago (Alkire et al, ) have provided well‐defined estimates of water chemistry, but over relatively constrained spatial scales, or—because of logistical constraints—based on a relatively small number of samples. In Canada in particular, we know little about the 75% of the Arctic‐flowing drainage that lies outside of the well‐characterized Mackenzie system (see also Alkire et al, and Godin et al, , for recent progress).…”

Section: Introductionmentioning

confidence: 99%

“…Measurements characterizing the biogeochemistry of smaller rivers in Alaska (Townsend‐Small et al, ), Siberia (Johnston et al, ), around Hudson Bay (Godin et al, ), and in the Canadian Arctic Archipelago (Alkire et al, ) have provided well‐defined estimates of water chemistry, but over relatively constrained spatial scales, or—because of logistical constraints—based on a relatively small number of samples. In Canada in particular, we know little about the 75% of the Arctic‐flowing drainage that lies outside of the well‐characterized Mackenzie system (see also Alkire et al, and Godin et al, , for recent progress). This lack of knowledge exists despite evidence of increasing fluxes of dissolved carbon and ions from several Canadian Arctic locations, which appear to be driven by thawing permafrost and other factors related to climate change (Kokelj et al, ; Spence et al, ; Tank et al, ).…”

Section: Introductionmentioning

confidence: 99%

Seasonal and Geographic Variation in Dissolved Carbon Biogeochemistry of Rivers Draining to the Canadian Arctic Ocean and Hudson Bay

et al. 2018

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The chemical composition of river water can be used to diagnose change on land, while playing a determining role in the ecology and biogeochemistry of riverine-influenced ocean waters. Despite this, little is known about the seasonal and geographic variability of riverine chemistry throughout much of the Canadian north. Here we assess the chemical composition of a broad suite of rivers draining to the Canadian Arctic Ocean and Hudson Bay using previously unpublished government data. We focus on inorganic and organic carbon (alkalinity and dissolved organic carbon), using paired chemistry and discharge measurements to assess constituent flux. Concentrations and area-normalized yields vary substantially across the northern Canadian landscape, with dissolved organic carbon typically highest in rivers draining the Hudson Bay Lowland, alkalinity highest in rivers draining Cordillera and Plains terrains, and the ratio of organic to inorganic species highest in rivers draining the Canadian Shield. Yields of major weathering ions show that carbonate weathering-a notable proportion of which may be driven by sulfide oxidation-dominates inorganic carbon delivery from the rivers we assess. Despite the reasonably diverse coverage of the data set, we find that clear gaps exist, including a lack of data through to the present day for many rivers, and a dearth of measurements from the Arctic Archipelago and eastern shores of Hudson Bay. We therefore use a modeling approach to extrapolate fluxes to the full Canadian Arctic drainage basin. Region-specific differences between our results and previous models reinforce the need for targeted river water chemistry measures throughout the Canadian Arctic domain.

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Organic matter compositions of rivers draining into Hudson Bay: Present-day trends and potential as recorders of future climate change

Cited by 29 publications

References 85 publications

Total organic carbon concentrations in ecosystem solutions of a remote tropical montane forest respond to global environmental change

Total organic carbon concentrations in ecosystem solutions of a remote tropical montane forest respond to global environmental change

Hurricanes Accelerate Dissolved Organic Carbon Cycling in Coastal Ecosystems

Seasonal and Geographic Variation in Dissolved Carbon Biogeochemistry of Rivers Draining to the Canadian Arctic Ocean and Hudson Bay

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