A spatially explicit model of iron loading to lakes

Maranger, Roxane; Canham, Charles D.; Pace, Michael L.; Papaik, Michael J.

doi:10.4319/lo.2006.51.1.0247

Cited by 18 publications

(16 citation statements)

References 44 publications

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“…As a result, areas of the same cover type high in the watershed contribute the same amount to loading as areas low in the watershed. This result is consistent with our previous studies of DOC and iron (Canham et al 2004, Maranger et al 2006 where the entire watershed, not just areas nearest lakes, provided source areas for export to lakes. To explore this point further, we considered if flowpaths from upland areas that passed through wetlands would show evidence of removal (or possibly enhancement) of N loading.…”

Section: Comparison Of Alternative Models Of N Export and Loadingsupporting

confidence: 82%

“…As in our previous work (Canham et al 2004, Maranger et al 2006, we have assumed that k is independent of stream length. Note that since the analysis is recursive, inputs from lakes located further up a lake chain are already taken into account when calculating the discharge from the immediately upstream lake.…”

Section: Lake Samplingmentioning

confidence: 99%

“…Our approach was based on the principles of mass-balance, in which variation in lake total nitrogen (TN) concentration is a balance between total inputs to the lake, primarily from the surrounding watershed, and net losses, primarily as a result of in-lake degradation and output in lake discharge (Canham et al 2004, Maranger et al 2006). Inputs to the lake are assumed to be independent of in-lake concentration, while losses are assumed to be proportional to in-lake concentration.…”

Section: Lake Samplingmentioning

confidence: 99%

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Nitrogen deposition and lake nitrogen concentrations: a regional analysis of terrestrial controls and aquatic linkages

et al. 2012

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Abstract. Loading of nutrients from terrestrial ecosystems strongly influences the productivity and biogeochemistry of aquatic ecosystems. Human activities can supplement and even dominate nutrient loading to many lakes, particularly in agricultural and urbanized settings. For lakes in more remote regions such as the Adirondack Mountains of New York, N deposition represents the primary potential anthropogenic nutrient source. We combined a spatial model of N deposition with data on lake-N concentrations and spatial data on watershed configuration to identify the sources of watershed N loading for over 250 lakes in the Adirondacks. The analysis indicates that while wetlands are stronger sources of N loading per unit area than forests in the absence of inorganic N deposition, wetlands retain essentially all N deposition, while forests retained ;87% of N deposition. Since forests cover close to 90% of the watersheds, upland forests are, on average, the single largest source of N loading to Adirondack lakes. Direct deposition of N to the lake surface accounted for as large a fraction of loading as that from wetlands in the watersheds. We found no evidence that presence of wetlands along flowpaths to lakes reduced loading from upland forests. Moreover, there was no evidence that net loading to lakes declined with increasing distance of a source area to the lake. Lake N-concentrations thus primarily reflect N-loading from forests in concert with loss rates determined by water residence time and within-lake processes.

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Section: Comparison Of Alternative Models Of N Export and Loadingsupporting

confidence: 82%

Section: Lake Samplingmentioning

confidence: 99%

Section: Lake Samplingmentioning

confidence: 99%

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Nitrogen deposition and lake nitrogen concentrations: a regional analysis of terrestrial controls and aquatic linkages

et al. 2012

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“…Hence, the fact that peatlands and coniferous forests act as important Fe sources (Bjorkvald et al, ; Kortelainen et al, ) is related to their relatively high DOM concentrations when compared to other types of land cover (Camino‐Serrano et al, ; Kalbitz et al, ). Peatland and forest soils often yield more dissolved Fe than mineral soils, although the latter soil type contains more bound Fe (Dillon & Molot, ; Kortelainen et al, ; Maranger et al, ). The Fe transport capacity is also affected by the organic matter composition, whereby high molecular weight DOM—such as fulvic and humic acids—act as important Fe carriers due to their high affinity for Fe (Laglera & van den Berg, ; Riise, ).…”

Section: Discussionmentioning

confidence: 99%

Widespread Increases in Iron Concentration in European and North American Freshwaters

Björnerås

Weyhenmeyer

Evans

et al. 2017

Global Biogeochemical Cycles

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Recent reports of increasing iron (Fe) concentrations in freshwaters are of concern, given the fundamental role of Fe in biogeochemical processes. Still, little is known about the frequency and geographical distribution of Fe trends or about the underlying drivers. We analyzed temporal trends of Fe concentrations across 340 water bodies distributed over 10 countries in northern Europe and North America in order to gain a clearer understanding of where, to what extent, and why Fe concentrations are on the rise. We found that Fe concentrations have significantly increased in 28% of sites, and decreased in 4%, with most positive trends located in northern Europe. Regions with rising Fe concentrations tend to coincide with those with organic carbon (OC) increases. Fe and OC increases may not be directly mechanistically linked, but may nevertheless be responding to common regional‐scale drivers such as declining sulfur deposition or hydrological changes. A role of hydrological factors was supported by covarying trends in Fe and dissolved silica, as these elements tend to stem from similar soil depths. A positive relationship between Fe increases and conifer cover suggests that changing land use and expanded forestry could have contributed to enhanced Fe export, although increases were also observed in nonforested areas. We conclude that the phenomenon of increasing Fe concentrations is widespread, especially in northern Europe, with potentially significant implications for wider ecosystem biogeochemistry, and for the current browning of freshwaters.

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“…In fact, Fe is soluble only under anoxic conditions, as FeII, or at strongly acidic pH, and it is the interaction between Fe and OM that maintain Fe in solution under conditions prevailing in these rivers out of which it would otherwise precipitate (Shapiro, 1966). Accordingly, an important pathway for Fe into surface waters is leaching from organic forest and wetland soils in complex with OM (Maranger et al, 2006). There is a spatial relationship between Fe and OM measured both as COD and TOC among the rivers.…”

Section: Why Is Fe Increasing?mentioning

confidence: 99%

Increasing iron concentrations in surface waters – a factor behind brownification?

2012

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Abstract. Browning of inland waters has been noted over large parts of the Northern hemisphere and is a phenomenon with both ecological and societal consequences. The increase in water color is generally ascribed to increasing concentrations of dissolved organic matter of terrestrial origin. However, oftentimes the increase in water color is larger than that of organic matter, implying that changes in the concentration of organic matter alone cannot explain the enhanced water color. Water color is known to be affected also by the quality of organic matter and the prevalence of iron. Here we investigated trends in water color, organic matter and iron between 1972 and 2010 in 30 rivers draining into the Swedish coast (data from the national Swedish monitoring program), and performed a laboratory iron addition experiment to natural waters, to evaluate the role of iron and organic matter in determining water color. By comparing the effect of iron additions on water color in the experiment, to variation in water color and iron concentration in the monitoring data, we show that iron can explain a significant share of the variation in water color (on average 25 %), especially in the rivers in the north of Sweden (up to 74 %). Furthermore, positive trends for iron are seen in 27 of 30 rivers (21-468 %) and the increase in iron is larger than that of organic matter, indicating that iron and organic matter concentrations are controlled by similar but not identical processes. We speculate that increasing iron concentrations can be caused by changes in redox conditions, that mean that more anoxic water with high concentrations of soluble FeII are feeding into the surface waters. More studies are needed about why iron is increasing so strongly, since both causes and consequences are partly different from those of increasing organic matter content.

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A spatially explicit model of iron loading to lakes

Cited by 18 publications

References 44 publications

Nitrogen deposition and lake nitrogen concentrations: a regional analysis of terrestrial controls and aquatic linkages

Nitrogen deposition and lake nitrogen concentrations: a regional analysis of terrestrial controls and aquatic linkages

Widespread Increases in Iron Concentration in European and North American Freshwaters

Increasing iron concentrations in surface waters – a factor behind brownification?

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