Multiyear Trends in Solute Concentrations and Fluxes From a Suburban Watershed: Evaluating Effects of 100‐Year Flood Events

Water Resources Research

McDowell

2020

Self Cite

High‐frequency in situ sensors have enabled researchers to measure solute concentrations at a time scale that captures the variability in stream discharge. We analyzed discrete samples and high‐frequency time series of solutes to characterize how nitrate (NO3−) and fluorescent dissolved organic matter (fDOM; a proxy for dissolved organic carbon) respond to changes in discharge at annual and intra‐annual timescales across a stream network in New Hampshire, USA. NO3− and fDOM exhibited highly variable concentration‐discharge (c‐Q) behavior at intra‐annual scales. Transport limitation, source limitation, and chemostatic behavior were observed to occur within and among years in all our study watersheds. Annual assessment of c‐Q misclassified streams 31% of the time, as the annual time step missed seasonal and event‐induced shifts in c‐Q dynamics. In some instances, anomalous events lasting less than 5% of the year determine the annual c‐Q behavior for a site. Catchment land use appeared to drive some of the variability among watersheds in c‐Q relationships and their temporal variability. Forested streams had highly variable NO3− c‐Q behavior and streams draining watersheds with more development had greater variability in fDOM c‐Q behavior. Sample frequency impacts how hydrologic systems are characterized and extrapolating c‐Q behavior from discrete samples alone can bias interpretations of c‐Q dynamics and our understanding of solute transport.

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Dissolved Organic Carbon and Nitrate Concentration‐Discharge Behavior Across Scales: Land Use, Excursions, and Misclassification

Fazekas

Water Resources Research

McDowell

2020

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“…estuary. In doing so, the data set captures continued changes in landuse and land-cover, population density and impervious cover (Coble et al, 2019), changing seasonality (Contosta et al, 2017), and multiple extreme events including two one-hundred-year scale floods (Coble et al, 2018). A compilation of associated publications using these long-term data can be found in Table 3.…”

Section: Long-term Data (20 Years)mentioning

confidence: 99%

“…Although the watershed remains heavily forested (73%), it is characterized as suburban and a mixed land-use environment incorporating agriculture (5%), development (7%) and wetlands (10%; NOAA Coastal Change Analysis Program, 2016). Human population has been increasing by 0.45 people km −2 year −1 since 1990 (60 people km −2 in 2020) with housing density at 25 housing units km −2 (Coble et al, 2018). A vast majority of the watershed's population utilizes on-site waste disposal (i.e., septic systems; Trowbridge et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

The Lamprey River Hydrological Observatory: Suburbanization and changing seasonality

Shattuck

Potter

et al. 2021

Hydrological Processes

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The Lamprey River Hydrological Observatory (LRHO) is a lowland coastal watershed in southeastern New Hampshire (USA). The LRHO offers a platform to investigate the effects of suburbanization and changing seasonality on watershed hydrology, biogeochemistry, and nutrient export to an estuarine ecosystem. The LRHO utilizes a nested-watershed design to examine headwater stream and main-stem river dynamics distributed across a mixed land-use environment. Data sets from the LRHO now comprise over 20 years of weekly grab sample data as well as 7 years of highfrequency sensor data. Collectively these data sets include measures of discharge, dissolved organic matter, nutrients, cations and anions, greenhouse gases, and other physio-chemical properties. Here we share information on the setting and motivating questions of the LRHO and data availability.

“…Although this approach has been used to understand the various controls on solutes and sediments across diverse environments (e.g., Johnson et al, 1969;Godsey et al, 2009;Herndon et al, 2018;Rose et al, 2018;Wymore et al, 2019), less attention has been given to the mobilization and transport of N and the implications for N cycling processes. And while certain forms of dissolved N (e.g., NO − 3 , DON) often do not appear to respond to changes in discharge across a broad range of flow conditions (Wymore et al, 2017;Coble et al, 2018), concentrations of NO − 3 do respond to changes in flow during individual storm events (Koenig et al, 2017a;Bernal et al, 2019) even when the overall relationship between concentration and discharge is weak. A detailed examination of how the different forms of dissolved N respond to changes in flow across diverse environments would help to elucidate the relative contribution Under elevated runoff, sediment concentrations increase due to the activation of addition flow paths and sources from the hillslope and watershed.…”

Section: Eq 3: How Do Concentrations and Fluxes Of Nitrogen Respond Tmentioning

confidence: 99%

LINX I and II: Lessons Learned and Emerging Questions

Rodriguez-Cardona

Herreid

et al. 2019

Front. Environ. Sci.

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The Lotic Intersite Nitrogen eXperiments (LINX I and II) were a series of replicated in situ manipulations of 15 N across biomes and land-uses designed to assess the factors that control the removal, retention, and ultimate fate of inorganic nitrogen in stream ecosystems. By studying streams at the continental scale, the lessons learned provide some of the best data available to understand the functional role of streams across the landscape, the management implications of nitrogen uptake in streams and rivers, and the value of small streams in elucidating fundamental principles of ecosystem science. Because small streams are characterized by high throughput and low standing stocks of primary producers and stored carbon and nutrients, they provide unique opportunities to assess the fundamental drivers of nitrogen cycling that would be difficult to conduct in other ecosystems. In addition to the water quality implications of understanding controls on nitrogen delivery to downstream systems, LINX I and II also provide unique insights for ecosystem science and stream ecology more broadly. Here we review a series of ecosystem and network-scale lessons that can be inferred from LINX I and II. We then propose three emergent research questions motivated by the LINX projects which are amenable to future continental-scale work. LINX I and II also demonstrate the value of a highly collaborative, distributed approach to ecosystem science that requires each member of the team to conduct a standardized protocol while simultaneously encouraging team member to improve protocols and develop cross-site projects in his or her specific area of expertise.