River Geomorphology Affects Biogeochemical Responses to Hydrologic Events in a Large River Ecosystem

Shifts in the frequency and intensity of high discharge events due to climate change may have important consequences for the hydrology and biogeochemistry of rivers. However, our understanding of event‐scale biogeochemical dynamics in large rivers lags that of small streams. To fill this gap, we used high‐frequency sensor data collected during four consecutive summers from a main channel and backwater site of the Upper Mississippi River. We identified high discharge events and calculated event concentration‐discharge responses for both physical‐chemical (nitrate, turbidity, and fluorescent dissolved organic matter) and biological (chlorophyll‐a and cyanobacteria) constituents using metrics of hysteresis and slope. We found a range of responses across events, particularly for nitrate. Although fluorescent dissolved organic matter (FDOM) and turbidity exhibited more consistent responses across events, contrasting hysteresis metrics indicated that FDOM was flushed to the river from more distant sources than turbidity. Biological responses (chlorophyll a and cyanobacteria) differed more between sites than physical and chemical constituents. Lastly, we found that the event characteristics best explaining concentration responses differed between sites, with event magnitude more frequently related to responses in the main channel, and antecedent wetness conditions associated with response variation in the backwater. Our results indicate that event responses in large rivers are distinct across the diverse habitats and biogeochemical components of a large floodplain river, which has implications for local and downstream ecosystems as the climate shifts.

[1]  M. Dornblaser,et al.  Dissolved Carbon Export by Large River Systems Is Influenced by Source Area Heterogeneity , 2023, Global Biogeochemical Cycles.

[2]  M. Peipoch,et al.  Deciphering the origin of riverine phytoplankton using in situ chlorophyll sensors , 2022, Limnology and Oceanography Letters.

[3]  W. McDowell,et al.  Climate Variability Drives Watersheds Along a Transporter‐Transformer Continuum , 2021, Geophysical Research Letters.

[4]  T. Royer,et al.  Storm size and hydrologic modification influence nitrate mobilization and transport in agricultural watersheds , 2021, Biogeochemistry.

[5]  E. Strauss,et al.  Spatial and temporal dynamics of phytoplankton assemblages in the upper Mississippi River , 2021, River Research and Applications.

[6]  M. Scheuerell,et al.  Warmer Winters Increase the Biomass of Phytoplankton in a Large Floodplain River , 2021 .

[7]  F. Fitzpatrick,et al.  Benthic and planktonic inorganic nutrient processing rates at the interface between a river and lake , 2021, Biogeochemistry.

[8]  J. N. Houser,et al.  Understanding Constraints on Submersed Vegetation Distribution in a Large, Floodplain River: the Role of Water Level Fluctuations, Water Clarity and River Geomorphology , 2021, Wetlands.

[9]  M. Zimmer,et al.  Hydrologic regimes drive nitrate export behavior in human-impacted watersheds , 2021, Hydrology and Earth System Sciences.

[10]  D. Robertson,et al.  Nitrogen and Phosphorus Sources and Delivery from the Mississippi/Atchafalaya River Basin: An Update Using 2012 SPARROW Models , 2021, JAWRA Journal of the American Water Resources Association.

[11]  E. Jeppesen,et al.  How hydrology and anthropogenic activity influence the molecular composition and export of dissolved organic matter: Observations along a large river continuum , 2021, Limnology and Oceanography.

[12]  Levi E. Solomon,et al.  Operational Impacts of a Water Management Structure on the Surrounding Fish Assemblages in a Restored Backwater and a Large Floodplain River , 2021, The American Midland Naturalist.

[13]  Mark S. Johnson,et al.  High-frequency analysis of dissolved organic carbon storm responses in headwater streams of contrasting forest harvest history , 2020 .

[14]  N. Basu,et al.  Is the River a Chemostat?: Scale Versus Land Use Controls on Nitrate Concentration‐Discharge Dynamics in the Upper Mississippi River Basin , 2020, Geophysical Research Letters.

[15]  J. Tank,et al.  Quantifying denitrification following floodplain restoration via the two-stage ditch in an agricultural watershed , 2020 .

[16]  W. McDowell,et al.  Dissolved Organic Carbon and Nitrate Concentration‐Discharge Behavior Across Scales: Land Use, Excursions, and Misclassification , 2020, Water Resources Research.

[17]  L. Weber,et al.  Source Switching Maintains Dissolved Organic Matter Chemostasis Across Discharge Levels in a Large Temperate River Network , 2020, Ecosystems.

[18]  M. M. Castillo Suspended sediment, nutrients, and chlorophyll in tropical floodplain lakes with different patterns of hydrological connectivity , 2020 .

[19]  Steven A. DeLain,et al.  Decadal trends and ecological shifts in backwater lakes of a large floodplain river: Upper Mississippi River , 2020, Aquatic Sciences.

[20]  J. Kirchner,et al.  Concentration–discharge relationships vary among hydrological events, reflecting differences in event characteristics , 2020, Hydrology and Earth System Sciences.

[21]  Jing Zhang,et al.  Sources, Transport, and Transformation of Dissolved Organic Matter in a Large River System: Illustrated by the Changjiang River, China , 2019, Journal of Geophysical Research: Biogeosciences.

[22]  E. Hotchkiss,et al.  Coupling Concentration‐ and Process‐Discharge Relationships Integrates Water Chemistry and Metabolism in Streams , 2019, Water Resources Research.

[23]  K. Fennel,et al.  Time-evolving, spatially explicit forecasts of the northern Gulf of Mexico hypoxic zone. , 2019, Environmental science & technology.

[24]  L. Sprague,et al.  Network Controls on Mean and Variance of Nitrate Loads from the Mississippi River to the Gulf of Mexico , 2019, Journal of Environmental Quality.

[25]  L. Sprague,et al.  Water-quality trends in US rivers: Exploring effects from streamflow trends and changes in watershed management. , 2019, The Science of the total environment.

[26]  W. Showers,et al.  Hysteresis analysis of nitrate dynamics in the Neuse River, NC. , 2019, The Science of the total environment.

[27]  A. Hamlet,et al.  Effects of 21st century climate change on seasonal flow regimes and hydrologic extremes over the Midwest and Great Lakes region of the US. , 2019, The Science of the total environment.

[28]  M. Zimmer,et al.  Temporal Variability in Nitrate‐Discharge Relationships in Large Rivers as Revealed by High‐Frequency Data , 2019, Water Resources Research.

[29]  M. Doyle,et al.  Scoured or suffocated: Urban stream ecosystems oscillate between hydrologic and dissolved oxygen extremes , 2018, Limnology and Oceanography.

[30]  O. Rakovec,et al.  Multimodel assessment of flood characteristics in four large river basins at global warming of 1.5, 2.0 and 3.0 K above the pre-industrial level , 2018, Environmental Research Letters.

[31]  P. Raymond,et al.  Generality of Hydrologic Transport Limitation of Watershed Organic Carbon Flux Across Ecoregions of the United States , 2018, Geophysical Research Letters.

[32]  E. Stanley,et al.  Limited nitrate retention capacity in the Upper Mississippi River , 2018, Environmental Research Letters.

[33]  John M. Melack,et al.  Concentration‐Discharge Responses to Storm Events in Coastal California Watersheds , 2017 .

[34]  Michelle D. Shattuck,et al.  Deconstructing the Effects of Flow on DOC, Nitrate, and Major Ion Interactions Using a High‐Frequency Aquatic Sensor Network , 2017 .

[35]  Vimal Mishra,et al.  Intercomparison of regional-scale hydrological models and climate change impacts projected for 12 large river basins worldwide—a synthesis , 2017 .

[36]  M. Church,et al.  What are the contemporary sources of sediment in the Mississippi River? , 2017 .

[37]  R. Striegl,et al.  Biological and land use controls on the isotopic composition of aquatic carbon in the Upper Mississippi River Basin , 2017 .

[38]  Arthur J. Gold,et al.  High‐frequency dissolved organic carbon and nitrate measurements reveal differences in storm hysteresis and loading in relation to land cover and seasonality , 2017 .

[39]  H. Laudon,et al.  Spatial and temporal patterns of dissolved organic matter quantity and quality in the Mississippi River Basin, 1997–2013 , 2017 .

[40]  B. Abbott,et al.  Elemental properties, hydrology, and biology interact to shape concentration‐discharge curves for carbon, nutrients, sediment, and major ions , 2017 .

[41]  Luis Samaniego,et al.  Cross‐scale intercomparison of climate change impacts simulated by regional and global hydrological models in eleven large river basins , 2017, Climatic Change.

[42]  N. Basu,et al.  Two centuries of nitrogen dynamics: Legacy sources and sinks in the Mississippi and Susquehanna River Basins , 2017 .

[43]  Jianhua Gao,et al.  Turbidity maximum formation and its seasonal variations in the Zhujiang (Pearl River) Estuary, southern China , 2016, Acta Oceanologica Sinica.

[44]  Beth Stauffer,et al.  Emerging Tools for Continuous Nutrient Monitoring Networks: Sensors Advancing Science and Water Resources Protection , 2016 .

[45]  Doerthe Tetzlaff,et al.  Linking high‐frequency DOC dynamics to the age of connected water sources , 2016 .

[46]  P. Massicotte,et al.  Along-stream transport and transformation of dissolved organic matter in a large tropical river , 2016 .

[47]  J. N. Houser Contrasts between channels and backwaters in a large, floodplain river: testing our understanding of nutrient cycling, phytoplankton abundance, and suspended solids dynamics , 2016, Freshwater Science.

[48]  M. Cardenas,et al.  Denitrification in the Mississippi River network controlled by flow through river bedforms , 2015 .

[49]  J. Sullivan,et al.  Ecosystem metabolism and nutrient dynamics in the main channel and backwaters of the Upper Mississippi River , 2015 .

[50]  E. Strauss,et al.  Flood pulse effects on nitrification in a floodplain forest impacted by herbivory, invasion, and restoration , 2015, Wetlands Ecology and Management.

[51]  S. Kanae,et al.  Global flood risk under climate change , 2013 .

[52]  J. N. Houser,et al.  Variation in water-mediated connectivity influences patch distributions of total N, total P, and TN:TP ratios in the Upper Mississippi River, USA , 2012, Freshwater Science.

[53]  V. Simeonov,et al.  Assessment of Water Quality in the Elbe River at Flood Water Conditions Based on Cluster Analysis, Principle Components Analysis, and Source Apportionment , 2012 .

[54]  Stephanie S. Day,et al.  Large shift in source of fine sediment in the upper Mississippi river. , 2011, Environmental science & technology.

[55]  R. Hirsch,et al.  Nitrate in the Mississippi River and Its Tributaries, 1980 to 2008: Are We Making Progress? , 2011, Environmental science & technology.

[56]  S. Hamilton,et al.  Thinking Outside the Channel: Modeling Nitrogen Cycling in Networked River Ecosystems , 2011 .

[57]  G. McIsaac,et al.  Sources of nitrate yields in the Mississippi River Basin. , 2010, Journal of environmental quality.

[58]  J. N. Houser,et al.  Longitudinal trends and discontinuities in nutrients, chlorophyll, and suspended solids in the Upper Mississippi River: implications for transport, processing, and export by large rivers , 2010, Hydrobiologia.

[59]  P. Raymond,et al.  Event controlled DOC export from forested watersheds , 2010 .

[60]  R. Sparks Forty years of science and management on the Upper Mississippi River: an analysis of the past and a view of the future , 2010, Hydrobiologia.

[61]  J. Fellman,et al.  Changes in the concentration, biodegradability, and fluorescent properties of dissolved organic matter during stormflows in coastal temperate watersheds , 2009 .

[62]  D. Burns What do hydrologists mean when they use the term flushing? , 2005 .

[63]  W. Richardson,et al.  Denitrification in the Upper Mississippi River: rates, controls, and contribution to nitrate flux , 2004 .

[64]  James W. Kirchner,et al.  The fine structure of water‐quality dynamics: the (high‐frequency) wave of the future , 2004 .

[65]  Heidi J. Imker,et al.  Nitrification in the Upper Mississippi River: patterns, controls, and contribution to the NO3− budget , 2004, Journal of the North American Benthological Society.

[66]  Tim Sellers,et al.  Phytoplankton production in a large, regulated river: A modeling and mass balance assessment , 2003 .

[67]  John R. Jones,et al.  Connectivity Influences Temporal Variation of Limnological Conditions in Missouri River Scour Lakes , 2003 .

[68]  P. Bukaveckas,et al.  Factors regulating autotrophy and heterotrophy in the main channel and an embayment of a large river impoundment , 2002, Aquatic Ecology.

[69]  Dubravko Justic,et al.  Modeling the impacts of decadal changes in riverine nutrient fluxes on coastal eutrophication near the Mississippi River Delta , 2002 .

[70]  G. Bornette,et al.  Connectivity and biocomplexity in waterbodies of riverine floodplains , 2002 .

[71]  J. Galloway,et al.  A stormflow/baseflow comparison of dissolved organic matter concentrations and bioavailability in an Appalachian stream , 2001 .

[72]  Chris D. Evans,et al.  Causes of concentration/discharge hysteresis and its potential as a tool for analysis of episode hydrochemistry , 1998 .

[73]  John R. Jones,et al.  Trophic status of Missouri River floodplanin lakes in relation to basin type and connectivity , 1997, Wetlands.

[74]  Thomas Hein,et al.  HYDROLOGICAL CONNECTIVITY AND FLOOD PULSES AS THE CENTRAL ASPECTS FOR THE INTEGRITY OF A RIVER-FLOODPLAIN SYSTEM , 1995 .

[75]  W. Richardson,et al.  Past, Present, and Future Concepts in Large River Ecology How rivers function and how human activities influence river processes , 1995 .

[76]  K. Bouska,et al.  Indicators of ecosystem structure and function for the Upper Mississippi River System , 2018 .

[77]  N. Jager,et al.  Habitat Needs Assessment‐II for the Upper Mississippi River Restoration Program: Linking science to management perspectives , 2018 .

[78]  Ding Yongjian,et al.  Precipitation trends and their impact on the discharge of China's four largest rivers, 1951-1998 , 2005 .

[79]  F. Triska,et al.  Nitrogen biogeochemistry and surface-subsurface exchange in streams , 2000 .

[80]  G. Czapar,et al.  [Water quality]. , 1992, Verhandelingen - Koninklijke Academie voor Geneeskunde van Belgie.

[81]  G. Minshall,et al.  The River Continuum Concept , 1980 .