Nutrient dynamics in an oligotrophic arctic stream monitored in situ by wet chemistry methods

Snyder, Lisle; Bowden, William B.

doi:10.1002/2013wr014317

Cited by 16 publications

(23 citation statements)

References 32 publications

(61 reference statements)

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“…However, McNamara et al (2008) reported increases in North Slope Alaska stream NO 3 − in early fall in some, but not all, years, with similar seasonal timing as our reported decrease in soil NO 3 − . Water sampled from the outlet of Toolik Lake continuously into early September in 2006 did not show a similar peak in NO 3 − (Snyder and Bowden 2014), although in 2011, local stream NO 3 − increased in mid-September (W.B. Bowden, personal communication), coinciding with the described decrease in soil NO 3 − in this study.…”

Section: Discussionsupporting

confidence: 53%

Seasonal patterns of soil nitrogen availability in moist acidic tundra

et al. 2017

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Our ability to predict effects of changing soil nitrogen (N) in Arctic tundra has been limited by our poor understanding of the intra-annual variability of soil N in this strongly seasonal ecosystem. Studies have shown that microbial biomass declines in spring accompanied by peaks in inorganic nutrients. However, subsequent to this early pulse, there are few high temporal resolution measurements during the growing season. We hypothesized that (1) low N would be maintained throughout the growing season, (2) peaks of total free primary amines (TFPA), ammonium (NH 4 + ), and nitrate (NO 3 − ) would follow a sequential pattern driven by mineralization and nitrification, and (3) a peak in soil N would occur as plants senesce. We conducted weekly measurements of TFPA, NH 4 + , and NO 3 − in two tundra sites, from soil thaw in spring to freeze in fall. At each site, NH 4 + peaks were followed by smaller peaks in NO 3 − , supporting the hypothesis that excess NH 4 + would be nitrified. Furthermore, peaks in NH 4 + were observed both shortly after leaf expansion and at plant senescence. The variation in timing between sites and the peaks in NH 4 + subsequent to thaw indicates that nutrient limitation in these ecosystems is more dynamic and spatially variable than previously thought.Key words: nitrogen availability, nitrogen mineralization, seasonality, moist acidic tundra, total free primary amines.Résumé : Notre capacité à prévoir les effets de l'azote (N) changeant dans les sols de la toundra arctique a été limitée par notre compréhension insuffisante de la variabilité au cours d'une même année de N des sols dans cet écosystème fortement saisonnier. Les études ont montré des baisses de biomasses microbiennes au printemps accompagnées de pics dans les substances nutritives inorganiques. Cependant, subséquemment à cette première pulsation, il y a peu de mesures de résolution temporelle élevée pendant la saison de croissance. Nous avons formulé l'hypothèse (1) qu'un faible niveau de N serait maintenu au cours de la saison de croissance, (2)

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Section: Discussionsupporting

confidence: 53%

Seasonal patterns of soil nitrogen availability in moist acidic tundra

et al. 2017

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“…As previously mentioned, the small size of the Imnavait watershed limits the time that waters are subjected to instream photochemical and microbial processing compared to the other study sites. Reduced channelized water transit times likely limit potential instream nitrification of available NH 4 + [ Wollheim et al ., ; Snyder and Bowden , ]. As such, we would expect NO 3 − concentrations to increase and NH 4 + concentrations to decrease further downstream from our Imnavait sampling locating, consistent with the patterns observed at the other larger study sites.…”

Section: Discussionmentioning

confidence: 99%

“…Photooxidation may account for 70-95% of total DOC processed in the water column of lakes and rivers in the region [Cory et al, 2013;Cory et al, 2014]. Similarly, photoammonification of DON [Bushaw et al, 1996;Grzybowski, 2002;Sereda et al, 2012], followed by immobilization or nitrification [Peterson et al, 1997;Wollheim et al, 2001;Snyder and Bowden, 2014], may be an important DON loss mechanism in these systems. Moreover, partial photooxidation stimulates microbial remineralization of otherwise recalcitrant DOC [Cory et al, 2014], and may promote additional DON microbial remineralization postsnowmelt as well.…”

Section: Dissolved Organic Nitrogen Seasonal Dynamicsmentioning

confidence: 99%

Seasonality of dissolved nitrogen from spring melt to fall freezeup in Alaskan Arctic tundra and mountain streams

Khosh¹,

McClelland²,

Jacobson

et al. 2017

J. Geophys. Res. Biogeosci.

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Predicting the response of dissolved nitrogen export from Arctic watersheds to climate change requires an improved understanding of seasonal nitrogen dynamics. Recent studies of Arctic rivers emphasize the importance of spring thaw as a time when large fluxes of nitrogen are exported from Arctic watersheds, but studies capturing the entire hydrologic year are rare. We examined the temporal variability of dissolved organic nitrogen (DON) and dissolved inorganic nitrogen (DIN) concentrations in six streams/rivers in Arctic Alaska from spring melt to fall freezeup (May through October) in 2009 and 2010. DON concentrations were generally high during snowmelt and declined as runoff decreased. DIN concentrations were low through the spring and summer and increased markedly during the late summer and fall, primarily due to an increase in nitrate. The high DIN concentrations were observed to occur when seasonal soil thaw depths were near maximum extents. Concurrent increases in DIN and DIN‐to‐chloride ratios suggest that net increases from nitrogen sources contributed to these elevated DIN concentrations. Our stream chemistry data, combined with soil thermistor data, suggest that downward penetration of water into seasonally thawed mineral soils, and reduction in biological nitrogen assimilation relative to remineralization, may increase DIN export from Arctic watersheds during the late summer and fall. While this is part of a natural cycle, improved understanding of seasonal nitrogen dynamics is particularly important now because warmer temperatures in the Arctic are causing earlier spring snowmelt and later fall freezeup in many regions.

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“…At the watershed-scale, continuous nitrate monitoring is proving useful for both calculating nutrient loading to downstream waters (Pellerin et al, 2014), as well as understanding the drivers of changes in water quality (Hensley et al, 2014). High frequency measurements are also critical to adequately characterize the variability in surface water nitrate and orthophosphate concentrations at some sites, especially during hydrologic events (Pellerin et al, 2012;Bende-Michl et al, 2013;Ferrant et al, 2013;Carey et al, 2014;Outram et al, 2014;Bowes et al, 2015;Sherson et al, 2015) and during periods when instream biological processing or other factors produce, consume, or alter nutrients prior to downstream export (Pellerin et al, 2009;Heffernan and Cohen, 2010;Cohen et al, 2013;Hensley et al, 2014;Snyder and Bowden, 2014). For example, diurnal nitrate patterns similar to those observed in the Potomac River (Figure 2) have been used to estimate rates and drivers of primary productivity in both freshwater (Heffernan and Cohen, 2010;Cohen et al, 2013) and coastal environments (Johnson et al, 2006;Collins et al, 2013).…”

Section: Advancing Our Understanding Of Watershed Processesmentioning

confidence: 99%

Emerging Tools for Continuous Nutrient Monitoring Networks: Sensors Advancing Science and Water Resources Protection

Pellerin

Stauffer

Young

et al. 2016

J American Water Resour Assoc

134

104

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Sensors and enabling technologies are becoming increasingly important tools for water quality monitoring and associated water resource management decisions. In particular, nutrient sensors are of interest because of the well-known adverse effects of nutrient enrichment on coastal hypoxia, harmful algal blooms, and impacts to human health. Accurate and timely information on nutrient concentrations and loads is integral to strategies designed to minimize risk to humans and manage the underlying drivers of water quality impairment. Using nitrate sensors as the primary example, we highlight the types of applications in freshwater and coastal environments that are likely to benefit from continuous, real-time nutrient data. The concurrent emergence of new tools to integrate, manage, and share large datasets is critical to the successful use of nutrient sensors and has made it possible for the field of continuous monitoring to rapidly move forward. We highlight several near-term opportunities for federal agencies, as well as the broader scientific and management community, that will help accelerate sensor development, build and leverage sites within a national network, and develop open data standards and data management protocols that are key to realizing the benefits of a largescale, integrated monitoring network. Investing in these opportunities will provide new information to guide management and policies designed to protect and restore our nation's water resources.(KEY TERMS: sensors; nutrients; water quality; information management.)

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Nutrient dynamics in an oligotrophic arctic stream monitored in situ by wet chemistry methods

Cited by 16 publications

References 32 publications

Seasonal patterns of soil nitrogen availability in moist acidic tundra

Seasonal patterns of soil nitrogen availability in moist acidic tundra

Seasonality of dissolved nitrogen from spring melt to fall freezeup in Alaskan Arctic tundra and mountain streams

Emerging Tools for Continuous Nutrient Monitoring Networks: Sensors Advancing Science and Water Resources Protection

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