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4. Organizational Principles of Hyporheic Exchange Flow and Biogeochemical Cycling in River Networks Across Scales

Author

Krause, Stefan, Abbott, Benjamin W., Baranov, Viktor, Bernal, Susana, Blaen, Phillip J., Datry, Thibault, Drummond, Jennifer D., Fleckenstein, Jan H., Gómez Vélez, Jesús, Hannah, David M., Knapp, Julia L.A., Kurz, Marie J., Lewandowski, Jörg, Martí, Eugènia, Mendoza-Lera, Clara, Milner, Alexander, Packman, Aaron I., Pinay, Gilles, Ward, Adam S., Zarnetske, Jay P., Krause, Stefan, Abbott, Benjamin W., Baranov, Viktor, Bernal, Susana, Blaen, Phillip J., Datry, Thibault, Drummond, Jennifer D., Fleckenstein, Jan H., Gómez Vélez, Jesús, Hannah, David M., Knapp, Julia L.A., Kurz, Marie J., Lewandowski, Jörg, Martí, Eugènia, Mendoza-Lera, Clara, Milner, Alexander, Packman, Aaron I., Pinay, Gilles, Ward, Adam S., and Zarnetske, Jay P.

Abstract

Hyporheic zones increase freshwater ecosystem resilience to hydrological extremes and global environmental change. However, current conceptualizations of hyporheic exchange, residence time distributions, and the associated biogeochemical cycling in streambed sediments do not always accurately explain the hydrological and biogeochemical complexity observed in streams and rivers. Specifically, existing conceptual models insufficiently represent the coupled transport and reactivity along groundwater and surface water flow paths, the role of autochthonous organic matter in streambed biogeochemical functioning, and the feedbacks between surface-subsurface ecological processes, both within and across spatial and temporal scales. While simplified approaches to these issues are justifiable and necessary for transferability, the exclusion of important hyporheic processes from our conceptualizations can lead to erroneous conclusions and inadequate understanding and management of interconnected surface water and groundwater environments. This is particularly true at the landscape scale, where the organizational principles of spatio-temporal dynamics of hyporheic exchange flow (HEF) and biogeochemical processes remain largely uncharacterized. This article seeks to identify the most important drivers and controls of HEF and biogeochemical cycling based on a comprehensive synthesis of findings from a wide range of river systems. We use these observations to test current paradigms and conceptual models, discussing the interactions of local-to-regional hydrological, geomorphological, and ecological controls of hyporheic zone functioning. This improved conceptualization of the landscape organizational principles of drivers of HEF and biogeochemical processes from reach to catchment scales will inform future river research directions and watershed management strategies.

Published
2022

8. BIFoR FACE : Water–soil–vegetation–atmosphere data from a temperate deciduous forest catchment, including under elevatedCO 2

Author

MacKenzie, A. Rob, primary, Krause, Stefan, additional, Hart, Kris M., additional, Thomas, Richard M., additional, Blaen, Phillip J., additional, Hamilton, R. Liz, additional, Curioni, Giulio, additional, Quick, Susan E., additional, Kourmouli, Angeliki, additional, Hannah, David M., additional, Comer‐Warner, Sophie A., additional, Brekenfeld, Nicolai, additional, Ullah, Sami, additional, and Press, Malcolm C., additional

Published
2021
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9. Spatial and temporal variation in river corridor exchange across a 5th-order mountain stream network

Author

Ward, Adam S., primary, Wondzell, Steven M., additional, Schmadel, Noah M., additional, Herzog, Skuyler, additional, Zarnetske, Jay P., additional, Baranov, Viktor, additional, Blaen, Phillip J., additional, Brekenfeld, Nicolai, additional, Chu, Rosalie, additional, Derelle, Romain, additional, Drummond, Jennifer, additional, Fleckenstein, Jan H., additional, Garayburu-Caruso, Vanessa, additional, Graham, Emily, additional, Hannah, David, additional, Harman, Ciaran J., additional, Hixson, Jase, additional, Knapp, Julia L. A., additional, Krause, Stefan, additional, Kurz, Marie J., additional, Lewandowski, Jörg, additional, Li, Angang, additional, Martí, Eugènia, additional, Miller, Melinda, additional, Milner, Alexander M., additional, Neil, Kerry, additional, Orsini, Luisa, additional, Packman, Aaron I., additional, Plont, Stephen, additional, Renteria, Lupita, additional, Roche, Kevin, additional, Royer, Todd, additional, Segura, Catalina, additional, Stegen, James, additional, Toyoda, Jason, additional, Hager, Jacqueline, additional, and Wisnoski, Nathan I., additional

Published
2019
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10. Using recirculating flumes and a response surface model to investigate the role of hyporheic exchange and bacterial diversity on micropollutant half-lives

Author

Jaeger, Anna, Coll, Claudia, Posselt, Malte, Mechelke, Jonas, Rutere, Cyrus, Betterle, Andrea, Raza, Muhammad, Mehrtens, Anne, Meinikmann, Karin, Portmann, Andrea, Singh, Tanu, Blaen, Phillip J., Krause, Stefan, Horn, Marcus A., Hollender, Juliane, Benskin, Jonathan P., Sobek, Anna, Lewandowski, Joerg, Jaeger, Anna, Coll, Claudia, Posselt, Malte, Mechelke, Jonas, Rutere, Cyrus, Betterle, Andrea, Raza, Muhammad, Mehrtens, Anne, Meinikmann, Karin, Portmann, Andrea, Singh, Tanu, Blaen, Phillip J., Krause, Stefan, Horn, Marcus A., Hollender, Juliane, Benskin, Jonathan P., Sobek, Anna, and Lewandowski, Joerg

Abstract

Enhancing the understanding of the fate of wastewater-derived organic micropollutants in rivers is crucial to improve risk assessment, regulatory decision making and river management. Hyporheic exchange and sediment bacterial diversity are two factors gaining increasing importance as drivers for micropollutant degradation, but are complex to study in field experiments and usually ignored in laboratory tests aimed to estimate environmental half-lives. Flume mesocosms are useful to investigate micropollutant degradation processes, bridging the gap between the field and batch experiments. However, few studies have used flumes in this context. We present a novel experimental setup using 20 recirculating flumes and a response surface model to study the influence of hyporheic exchange and sediment bacterial diversity on half-lives of the anti-epileptic drug carbamazepine (CBZ) and the artificial sweetener acesulfame (ACS). The effect of bedform-induced hyporheic exchange was tested by three treatment levels differing in number of bedforms (0, 3 and 6). Three levels of sediment bacterial diversity were obtained by diluting sediment from the River Erpe in Berlin, Germany, with sand (1 : 10, 1 : 1000 and 1 : 100 000). Our results show that ACS half-lives were significantly influenced by sediment dilution and number of bedforms. Half-lives of CBZ were higher than ACS, and were significantly affected only by the sediment dilution variable, and thus by bacterial diversity. Our results show that (1) the flume-setup is a useful tool to study the fate of micropollutants in rivers, and that (2) higher hyporheic exchange and bacterial diversity in the sediment can increase the degradation of micropollutants in rivers.

Published
2019
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11. Spatial and temporal variation in river corridor exchange across a 5th-order mountain stream network

Author

Ward, Adam S., Wondzell, Steven M., Schmadel, Noah M., Herzog, Skuyler, Zarnetske, Jay P., Baranov, Viktor, Blaen, Phillip J., Brekenfeld, Nicolai, Chu, Rosalie, Derelle, Romain, Drummond, Jennifer D., Fleckenstein, Jan H., Garayburu-Caruso, Vanessa, Graham, Emily B., Hannah, David, Harman, Ciaran J., Hixson, Jase, Knapp, Julia L. A., Krause, Stefan, Kurz, Marie J., Lewandowski, Joerg, Li, Angang, Marti, Eugenia, Miller, Melinda C., Milner, Alexander M., Neil, Kerry, Orsini, Luisa, Packman, Aaron I., Plont, Stephen, Renteria, Lupita, Roche, Kevin, Royer, Todd, Segura, Catalina, Stegen, James, Toyoda, Jason, Wells, Jacqueline, Wisnoski, Nathan I., Ward, Adam S., Wondzell, Steven M., Schmadel, Noah M., Herzog, Skuyler, Zarnetske, Jay P., Baranov, Viktor, Blaen, Phillip J., Brekenfeld, Nicolai, Chu, Rosalie, Derelle, Romain, Drummond, Jennifer D., Fleckenstein, Jan H., Garayburu-Caruso, Vanessa, Graham, Emily B., Hannah, David, Harman, Ciaran J., Hixson, Jase, Knapp, Julia L. A., Krause, Stefan, Kurz, Marie J., Lewandowski, Joerg, Li, Angang, Marti, Eugenia, Miller, Melinda C., Milner, Alexander M., Neil, Kerry, Orsini, Luisa, Packman, Aaron I., Plont, Stephen, Renteria, Lupita, Roche, Kevin, Royer, Todd, Segura, Catalina, Stegen, James, Toyoda, Jason, Wells, Jacqueline, and Wisnoski, Nathan I.

Abstract

Although most field and modeling studies of river corridor exchange have been conducted at scales ranging from tens to hundreds of meters, results of these studies are used to predict their ecological and hydrological influences at the scale of river networks. Further complicating prediction, exchanges are expected to vary with hydrologic forcing and the local geomorphic setting. While we desire predictive power, we lack a complete spatiotemporal relationship relating discharge to the variation in geologic setting and hydrologic forcing that is expected across a river basin. Indeed, the conceptual model of Wondzell (2011) predicts systematic variation in river corridor exchange as a function of (1) variation in baseflow over time at a fixed location, (2) variation in discharge with location in the river network, and (3) local geomorphic setting. To test this conceptual model we conducted more than 60 solute tracer studies including a synoptic campaign in the 5th-order river network of the H. J. Andrews Experimental Forest (Oregon, USA) and replicate-intime experiments in four watersheds. We interpret the data using a series of metrics describing river corridor exchange and solute transport, testing for consistent direction and magnitude of relationships relating these metrics to discharge and local geomorphic setting. We confirmed systematic decrease in river corridor exchange space through the river networks, from headwaters to the larger main stem. However, we did not find systematic variation with changes in discharge through time or with local geomorphic setting. While interpretation of our results is complicated by problems with the analytical methods, the results are sufficiently robust for us to conclude that space-for-time and time-for-space substitutions are not appropriate in our study system. Finally, we suggest two strategies that will improve the interpretability of tracer test results and help the hyporheic community develop robust datasets that will e

Published
2019
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12. Co-located contemporaneous mapping of morphological, hydrological, chemical, and biological conditions in a 5th-order mountain stream network, Oregon, USA

Author

Ward, Adam S., Zarnetske, Jay P., Baranov, Viktor, Blaen, Phillip J., Brekenfeld, Nicolai, Chu, Rosalie, Derelle, Romain, Drummond, Jennifer D., Fleckenstein, Jan H., Garayburu-Caruso, Vanessa, Graham, Emily B., Hannah, David, Harman, Ciaran J., Herzog, Skuyler, Hixson, Jase, Knapp, Julia L. A., Krause, Stefan, Kurz, Marie J., Lewandowski, Joerg, Li, Angang, Marti, Eugenia, Miller, Melinda C., Milner, Alexander M., Neil, Kerry, Orsini, Luisa, Packman, Aaron I., Plont, Stephen, Renteria, Lupita, Roche, Kevin, Royer, Todd, Schmadel, Noah M., Segura, Catalina, Stegen, James, Toyoda, Jason, Wells, Jacqueline, Wisnoski, Nathan I., Wondzell, Steven M., Ward, Adam S., Zarnetske, Jay P., Baranov, Viktor, Blaen, Phillip J., Brekenfeld, Nicolai, Chu, Rosalie, Derelle, Romain, Drummond, Jennifer D., Fleckenstein, Jan H., Garayburu-Caruso, Vanessa, Graham, Emily B., Hannah, David, Harman, Ciaran J., Herzog, Skuyler, Hixson, Jase, Knapp, Julia L. A., Krause, Stefan, Kurz, Marie J., Lewandowski, Joerg, Li, Angang, Marti, Eugenia, Miller, Melinda C., Milner, Alexander M., Neil, Kerry, Orsini, Luisa, Packman, Aaron I., Plont, Stephen, Renteria, Lupita, Roche, Kevin, Royer, Todd, Schmadel, Noah M., Segura, Catalina, Stegen, James, Toyoda, Jason, Wells, Jacqueline, Wisnoski, Nathan I., and Wondzell, Steven M.

Abstract

A comprehensive set of measurements and calculated metrics describing physical, chemical, and biological conditions in the river corridor is presented. These data were collected in a catchment-wide, synoptic campaign in the H. J. Andrews Experimental Forest (Cascade Mountains, Oregon, USA) in summer 2016 during low-discharge conditions. Extensive characterization of 62 sites including surface water, hyporheic water, and streambed sediment was conducted spanning 1st- through 5th-order reaches in the river network. The objective of the sample design and data acquisition was to generate a novel data set to support scaling of river corridor processes across varying flows and morphologic forms present in a river network. The data are available at https://doi.org/10.4211/hs.f4484e0703f743c696c2e1f209abb842 (Ward, 2019).

Published
2019
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13. Solute Transport and Transformation in an Intermittent, Headwater Mountain Stream with Diurnal Discharge Fluctuations

Author

Ward, Adam S., Kurz, Marie J., Schmadel, Noah M., Knapp, Julia L. A., Blaen, Phillip J., Harman, Ciaran J., Drummond, Jennifer D., Hannah, David M., Krause, Stefan, Li, Angang, Marti, Eugenia, Milner, Alexander M., Miller, Melinda C., Neil, Kerry, Plont, Stephen, Packman, Aaron I., Wisnoski, Nathan I., Wondzell, Steven M., Zarnetske, Jay P., Ward, Adam S., Kurz, Marie J., Schmadel, Noah M., Knapp, Julia L. A., Blaen, Phillip J., Harman, Ciaran J., Drummond, Jennifer D., Hannah, David M., Krause, Stefan, Li, Angang, Marti, Eugenia, Milner, Alexander M., Miller, Melinda C., Neil, Kerry, Plont, Stephen, Packman, Aaron I., Wisnoski, Nathan I., Wondzell, Steven M., and Zarnetske, Jay P.

Abstract

Time-variable discharge is known to control both transport and transformation of solutes in the river corridor. Still, few studies consider the interactions of transport and transformation together. Here, we consider how diurnal discharge fluctuations in an intermittent, headwater stream control reach-scale solute transport and transformation as measured with conservative and reactive tracers during a period of no precipitation. One common conceptual model is that extended contact times with hyporheic zones during low discharge conditions allows for increased transformation of reactive solutes. Instead, we found tracer timescales within the reach were related to discharge, described by a single discharge-variable StorAge Selection function. We found that Resazurin to Resorufin (Raz-to-Rru) transformation is static in time, and apparent differences in reactive tracer were due to interactions with different ages of storage, not with time-variable reactivity. Overall we found reactivity was highest in youngest storage locations, with minimal Raz-to-Rru conversion in waters older than about 20 h of storage in our study reach. Therefore, not all storage in the study reach has the same potential biogeochemical function and increasing residence time of solute storage does not necessarily increase reaction potential of that solute, contrary to prevailing expectations.

Published
2019
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14. Spatial and temporal variation in river corridor exchange across a 5th-order mountain stream network

Author

Biological Sciences, Ward, Adam S., Wondzell, Steven M., Schmadel, Noah M., Herzog, Skuyler, Zarnetske, Jay P., Baranov, Viktor, Blaen, Phillip J., Brekenfeld, Nicolai, Chu, Rosalie, Derelle, Romain, Drummond, Jennifer D., Fleckenstein, Jan H., Garayburu-Caruso, Vanessa, Graham, Emily B., Hannah, David, Harman, Ciaran J., Hixson, Jase, Knapp, Julia L. A., Krause, Stefan, Kurz, Marie J., Lewandowski, Joerg, Li, Angang, Marti, Eugenia, Miller, Melinda C., Milner, Alexander M., Neil, Kerry, Orsini, Luisa, Packman, Aaron I., Plont, Stephen, Renteria, Lupita, Roche, Kevin, Royer, Todd, Segura, Catalina, Stegen, James, Toyoda, Jason, Wells, Jacqueline, Wisnoski, Nathan I., Biological Sciences, Ward, Adam S., Wondzell, Steven M., Schmadel, Noah M., Herzog, Skuyler, Zarnetske, Jay P., Baranov, Viktor, Blaen, Phillip J., Brekenfeld, Nicolai, Chu, Rosalie, Derelle, Romain, Drummond, Jennifer D., Fleckenstein, Jan H., Garayburu-Caruso, Vanessa, Graham, Emily B., Hannah, David, Harman, Ciaran J., Hixson, Jase, Knapp, Julia L. A., Krause, Stefan, Kurz, Marie J., Lewandowski, Joerg, Li, Angang, Marti, Eugenia, Miller, Melinda C., Milner, Alexander M., Neil, Kerry, Orsini, Luisa, Packman, Aaron I., Plont, Stephen, Renteria, Lupita, Roche, Kevin, Royer, Todd, Segura, Catalina, Stegen, James, Toyoda, Jason, Wells, Jacqueline, and Wisnoski, Nathan I.

Abstract

Although most field and modeling studies of river corridor exchange have been conducted at scales ranging from tens to hundreds of meters, results of these studies are used to predict their ecological and hydrological influences at the scale of river networks. Further complicating prediction, exchanges are expected to vary with hydrologic forcing and the local geomorphic setting. While we desire predictive power, we lack a complete spatiotemporal relationship relating discharge to the variation in geologic setting and hydrologic forcing that is expected across a river basin. Indeed, the conceptual model of Wondzell (2011) predicts systematic variation in river corridor exchange as a function of (1) variation in baseflow over time at a fixed location, (2) variation in discharge with location in the river network, and (3) local geomorphic setting. To test this conceptual model we conducted more than 60 solute tracer studies including a synoptic campaign in the 5th-order river network of the H. J. Andrews Experimental Forest (Oregon, USA) and replicate-intime experiments in four watersheds. We interpret the data using a series of metrics describing river corridor exchange and solute transport, testing for consistent direction and magnitude of relationships relating these metrics to discharge and local geomorphic setting. We confirmed systematic decrease in river corridor exchange space through the river networks, from headwaters to the larger main stem. However, we did not find systematic variation with changes in discharge through time or with local geomorphic setting. While interpretation of our results is complicated by problems with the analytical methods, the results are sufficiently robust for us to conclude that space-for-time and time-for-space substitutions are not appropriate in our study system. Finally, we suggest two strategies that will improve the interpretability of tracer test results and help the hyporheic community develop robust datasets that will e

Published
2019

15. Solute Transport and Transformation in an Intermittent, Headwater Mountain Stream with Diurnal Discharge Fluctuations

Author

Biological Sciences, Ward, Adam S., Kurz, Marie J., Schmadel, Noah M., Knapp, Julia L. A., Blaen, Phillip J., Harman, Ciaran J., Drummond, Jennifer D., Hannah, David M., Krause, Stefan, Li, Angang, Marti, Eugenia, Milner, Alexander M., Miller, Melinda C., Neil, Kerry, Plont, Stephen, Packman, Aaron I., Wisnoski, Nathan I., Wondzell, Steven M., Zarnetske, Jay P., Biological Sciences, Ward, Adam S., Kurz, Marie J., Schmadel, Noah M., Knapp, Julia L. A., Blaen, Phillip J., Harman, Ciaran J., Drummond, Jennifer D., Hannah, David M., Krause, Stefan, Li, Angang, Marti, Eugenia, Milner, Alexander M., Miller, Melinda C., Neil, Kerry, Plont, Stephen, Packman, Aaron I., Wisnoski, Nathan I., Wondzell, Steven M., and Zarnetske, Jay P.

Abstract

Time-variable discharge is known to control both transport and transformation of solutes in the river corridor. Still, few studies consider the interactions of transport and transformation together. Here, we consider how diurnal discharge fluctuations in an intermittent, headwater stream control reach-scale solute transport and transformation as measured with conservative and reactive tracers during a period of no precipitation. One common conceptual model is that extended contact times with hyporheic zones during low discharge conditions allows for increased transformation of reactive solutes. Instead, we found tracer timescales within the reach were related to discharge, described by a single discharge-variable StorAge Selection function. We found that Resazurin to Resorufin (Raz-to-Rru) transformation is static in time, and apparent differences in reactive tracer were due to interactions with different ages of storage, not with time-variable reactivity. Overall we found reactivity was highest in youngest storage locations, with minimal Raz-to-Rru conversion in waters older than about 20 h of storage in our study reach. Therefore, not all storage in the study reach has the same potential biogeochemical function and increasing residence time of solute storage does not necessarily increase reaction potential of that solute, contrary to prevailing expectations.

Published
2019

16. Co-located contemporaneous mapping of morphological, hydrological, chemical, and biological conditions in a 5th-order mountain stream network, Oregon, USA

Author

Biological Sciences, Ward, Adam S., Zarnetske, Jay P., Baranov, Viktor, Blaen, Phillip J., Brekenfeld, Nicolai, Chu, Rosalie, Derelle, Romain, Drummond, Jennifer D., Fleckenstein, Jan H., Garayburu-Caruso, Vanessa, Graham, Emily B., Hannah, David, Harman, Ciaran J., Herzog, Skuyler, Hixson, Jase, Knapp, Julia L. A., Krause, Stefan, Kurz, Marie J., Lewandowski, Joerg, Li, Angang, Marti, Eugenia, Miller, Melinda C., Milner, Alexander M., Neil, Kerry, Orsini, Luisa, Packman, Aaron I., Plont, Stephen, Renteria, Lupita, Roche, Kevin, Royer, Todd, Schmadel, Noah M., Segura, Catalina, Stegen, James, Toyoda, Jason, Wells, Jacqueline, Wisnoski, Nathan I., Wondzell, Steven M., Biological Sciences, Ward, Adam S., Zarnetske, Jay P., Baranov, Viktor, Blaen, Phillip J., Brekenfeld, Nicolai, Chu, Rosalie, Derelle, Romain, Drummond, Jennifer D., Fleckenstein, Jan H., Garayburu-Caruso, Vanessa, Graham, Emily B., Hannah, David, Harman, Ciaran J., Herzog, Skuyler, Hixson, Jase, Knapp, Julia L. A., Krause, Stefan, Kurz, Marie J., Lewandowski, Joerg, Li, Angang, Marti, Eugenia, Miller, Melinda C., Milner, Alexander M., Neil, Kerry, Orsini, Luisa, Packman, Aaron I., Plont, Stephen, Renteria, Lupita, Roche, Kevin, Royer, Todd, Schmadel, Noah M., Segura, Catalina, Stegen, James, Toyoda, Jason, Wells, Jacqueline, Wisnoski, Nathan I., and Wondzell, Steven M.

Abstract

A comprehensive set of measurements and calculated metrics describing physical, chemical, and biological conditions in the river corridor is presented. These data were collected in a catchment-wide, synoptic campaign in the H. J. Andrews Experimental Forest (Cascade Mountains, Oregon, USA) in summer 2016 during low-discharge conditions. Extensive characterization of 62 sites including surface water, hyporheic water, and streambed sediment was conducted spanning 1st- through 5th-order reaches in the river network. The objective of the sample design and data acquisition was to generate a novel data set to support scaling of river corridor processes across varying flows and morphologic forms present in a river network. The data are available at https://doi.org/10.4211/hs.f4484e0703f743c696c2e1f209abb842 (Ward, 2019).

Published
2019

17. Solute transport and transformation in an intermittent, headwater mountain stream with diurnal discharge fluctuations

Author

Department of Energy (US), Leverhulme Trust, Natural Environment Research Council (UK), European Commission, National Science Foundation (US), Ward, Adam S., Kurz, Marie J., Schmadel, Noah M., Knapp, Julia L.A., Blaen, Phillip J., Harman, Ciaran J., Drummond, Jennifer D., Hannah, David M., Krause, Stefan, Li, Angang, Martí, Eugènia, Milner, Alexander, Miller, Melinda, Neil, Kerry, Plont, Stephen, Packman, Aaron I., Wisnoski, Nathan I., Wondzell, Steven M., Zarnetske, Jay P., Department of Energy (US), Leverhulme Trust, Natural Environment Research Council (UK), European Commission, National Science Foundation (US), Ward, Adam S., Kurz, Marie J., Schmadel, Noah M., Knapp, Julia L.A., Blaen, Phillip J., Harman, Ciaran J., Drummond, Jennifer D., Hannah, David M., Krause, Stefan, Li, Angang, Martí, Eugènia, Milner, Alexander, Miller, Melinda, Neil, Kerry, Plont, Stephen, Packman, Aaron I., Wisnoski, Nathan I., Wondzell, Steven M., and Zarnetske, Jay P.

Abstract

Time-variable discharge is known to control both transport and transformation of solutes in the river corridor. Still, few studies consider the interactions of transport and transformation together. Here, we consider how diurnal discharge fluctuations in an intermittent, headwater stream control reach-scale solute transport and transformation as measured with conservative and reactive tracers during a period of no precipitation. One common conceptual model is that extended contact times with hyporheic zones during low discharge conditions allows for increased transformation of reactive solutes. Instead, we found tracer timescales within the reach were related to discharge, described by a single discharge-variable StorAge Selection function. We found that Resazurin to Resorufin (Raz-to-Rru) transformation is static in time, and apparent differences in reactive tracer were due to interactions with different ages of storage, not with time-variable reactivity. Overall we found reactivity was highest in youngest storage locations, with minimal Raz-to-Rru conversion in waters older than about 20 h of storage in our study reach. Therefore, not all storage in the study reach has the same potential biogeochemical function and increasing residence time of solute storage does not necessarily increase reaction potential of that solute, contrary to prevailing expectations.

Published
2019

18. Co-located contemporaneous mapping of morphological, hydrological, chemical, and biological conditions in a 5th-order mountain stream network, Oregon, USA

Author

Ward, Adam S., primary, Zarnetske, Jay P., additional, Baranov, Viktor, additional, Blaen, Phillip J., additional, Brekenfeld, Nicolai, additional, Chu, Rosalie, additional, Derelle, Romain, additional, Drummond, Jennifer, additional, Fleckenstein, Jan H., additional, Garayburu-Caruso, Vanessa, additional, Graham, Emily, additional, Hannah, David, additional, Harman, Ciaran J., additional, Herzog, Skuyler, additional, Hixson, Jase, additional, Knapp, Julia L. A., additional, Krause, Stefan, additional, Kurz, Marie J., additional, Lewandowski, Jörg, additional, Li, Angang, additional, Martí, Eugènia, additional, Miller, Melinda, additional, Milner, Alexander M., additional, Neil, Kerry, additional, Orsini, Luisa, additional, Packman, Aaron I., additional, Plont, Stephen, additional, Renteria, Lupita, additional, Roche, Kevin, additional, Royer, Todd, additional, Schmadel, Noah M., additional, Segura, Catalina, additional, Stegen, James, additional, Toyoda, Jason, additional, Hager, Jacqueline, additional, Wisnoski, Nathan I., additional, and Wondzell, Steven M., additional

Published
2019
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19. Using recirculating flumes and a response surface model to investigate the role of hyporheic exchange and bacterial diversity on micropollutant half-lives

Author

Jaeger, Anna, primary, Coll, Claudia, additional, Posselt, Malte, additional, Mechelke, Jonas, additional, Rutere, Cyrus, additional, Betterle, Andrea, additional, Raza, Muhammad, additional, Mehrtens, Anne, additional, Meinikmann, Karin, additional, Portmann, Andrea, additional, Singh, Tanu, additional, Blaen, Phillip J., additional, Krause, Stefan, additional, Horn, Marcus A., additional, Hollender, Juliane, additional, Benskin, Jonathan P., additional, Sobek, Anna, additional, and Lewandowski, Joerg, additional

Published
2019
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20. BIFoR FACE: Water–soil–vegetation–atmosphere data from a temperate deciduous forest catchment, including under elevated CO2.

Author

MacKenzie, A. Rob, Krause, Stefan, Hart, Kris M., Thomas, Richard M., Blaen, Phillip J., Hamilton, R. Liz, Curioni, Giulio, Quick, Susan E., Kourmouli, Angeliki, Hannah, David M., Comer‐Warner, Sophie A., Brekenfeld, Nicolai, Ullah, Sami, and Press, Malcolm C.

Subjects
ATMOSPHERIC carbon dioxide, SOIL moisture, NUTRIENT cycles, HYDROLOGY, SOIL temperature, FORESTED wetlands, WATERSHEDS, DECIDUOUS forests
Abstract

The ecosystem services provided by forests modulate runoff generation processes, nutrient cycling and water and energy exchange between soils, vegetation and atmosphere. Increasing atmospheric CO2 affects many linked aspects of forest and catchment function in ways we do not adequately understand. Global levels of atmospheric CO2 will be around 40% higher in 2050 than current levels, yet estimates of how water and solute fluxes in forested catchments will respond to increased CO2 are highly uncertain. The Free Air CO2 Enrichment (FACE) facility of the University of Birmingham's Institute of Forest Research (BIFoR) is the only FACE in mature deciduous forest. The site specializes in fundamental studies of the response of whole ecosystem patches of mature, deciduous, temperate woodland to elevated CO2 (eCO2). Here, we describe a dataset of hydrological parameters – seven weather parameters at each of three heights and four locations, shallow soil moisture and temperature, stream hydrology and CO2 enrichment – retrieved at high frequency from the BIFoR FACE catchment. [ABSTRACT FROM AUTHOR]

Published
2021
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21. High-frequency monitoring of catchment nutrient exports reveals highly variable storm event responses and dynamic source zone activation

Author

Blaen, Phillip J., Khamis, Kieran, Lloyd, Charlotte, Comer-Warner, Sophie, Ciocca, Francesco, Thomas, Rick M., MacKenzie, A. Rob, and Krause, Stefan

Subjects
Nutrients and nutrient cycling, Water quality, Extreme events, Hydroclimatology, Monitoring networks, sensor, in situ, NO3, DOC, river, hysteresis
Abstract

Storm events can drive highly variable behavior in catchment nutrient and water fluxes, yet short-term event dynamics are frequently missed by low-resolution sampling regimes. In addition, nutrient source zone contributions can vary significantly within and between storm events. Our inability to identify and characterize time-dynamic source zone contributions severely hampers the adequate design of land use management practices in order to control nutrient exports from agricultural landscapes. Here we utilize an 8 month high-frequency (hourly) time series of streamflow, nitrate (NO3-N), dissolved organic carbon (DOC), and hydroclimatic variables for a headwater agricultural catchment. We identified 29 distinct storm events across the monitoring period. These events represented 31% of the time series and contributed disproportionately to nutrient loads (42% of NO3-N and 43% of DOC) relative to their duration. Regression analysis identified a small subset of hydroclimatological variables (notably precipitation intensity and antecedent conditions) as key drivers of nutrient dynamics during storm events. Hysteresis analysis of nutrient concentration-discharge relationships highlighted the dynamic activation of discrete NO3-N and DOC source zones, which varied on an event-specific basis. Our results highlight the benefits of high-frequency in situ monitoring for characterizing short-term nutrient fluxes and unraveling connections between hydroclimatological variability and river nutrient export and source zone activation under extreme flow conditions. These new process-based insights, which we summarize in a conceptual model, are fundamental to underpinning targeted management measures to reduce nutrient loading of surface waters.

Published
2017

26. Stream solute tracer timescales changing with discharge and reach length confound process interpretation

Author

Schmadel, Noah M., primary, Ward, Adam S., additional, Kurz, Marie J., additional, Fleckenstein, Jan H., additional, Zarnetske, Jay P., additional, Hannah, David M., additional, Blume, Theresa, additional, Vieweg, Michael, additional, Blaen, Phillip J., additional, Schmidt, Christian, additional, Knapp, Julia L.A., additional, Klaar, Megan J., additional, Romeijn, Paul, additional, Datry, Thibault, additional, Keller, Toralf, additional, Folegot, Silvia, additional, Arricibita, Amaia I. Marruedo, additional, and Krause, Stefan, additional

Published
2016
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31. Water source dynamics of high Arctic river basins.

Author

Blaen, Phillip J., Hannah, David M., Brown, Lee E., and Milner, Alexander M.

Subjects
WATER supply, WATERSHEDS, HYDROLOGY, RUNOFF
Abstract

Arctic river basins are amongst the most vulnerable to climate change. However, there is currently limited knowledge of the hydrological processes that govern flow dynamics in Arctic river basins. We address this research gap using natural hydrochemical and isotopic tracers to identify water sources that contributed to runoff in river basins spanning a gradient of glacierization (0-61%) in Svalbard during summer 2010 and 2011. Spatially distinct hydrological processes operating over diurnal, weekly and seasonal timescales were characterized by river hydrochemistry and isotopic composition. Two conceptual water sources ('meltwater' and 'groundwater') were identified and used as a basis for end-member mixing analyses to assess seasonal and year-to-year variability in water source dynamics. In glacier-fed rivers, meltwater dominated flows at all sites (typically >80%) with the highest contributions observed at the beginning of each study period in early July when snow cover was most extensive. Rivers in non-glacierized basins were sourced initially from snowmelt but became increasingly dependent on groundwater inputs (up to 100% of total flow volume) by late summer. These hydrological changes were attributed to the depletion of snowpacks and enhanced soil water storage capacity as the active layer expanded throughout each melt season. These findings provide insight into the processes that underpin water source dynamics in Arctic river systems and potential future changes in Arctic hydrology that might be expected under a changing climate. Copyright © 2013 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published
2014
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32. Environmental drivers of macroinvertebrate communities in high Arctic rivers ( Svalbard).

Author

Blaen, Phillip J., Brown, Lee E., Hannah, David M., and Milner, Alexander M.

Subjects
*INVERTEBRATE communities, *CLIMATE change, *FRESHWATER biodiversity, *HABITATS, *BENTHIC animals
Abstract

The impacts of climate-induced environmental changes on freshwater biodiversity are not well understood in Arctic regions., We quantified water source contributions (meltwater, ground water), environmental habitat conditions and benthic macroinvertebrate community dynamics in north-west Svalbard. The aim was to use contemporary findings to infer how future environmental change may affect these Arctic river ecosystems., Water source dynamics played an important role in influencing environmental habitat conditions; meltwater contributions to flow were related significantly to discharge, channel stability, electrical conductivity and p H., Low regional benthic macroinvertebrate diversity relative to other Arctic regions was attributed to harsh winter conditions and biogeographical dispersal constraints associated with the Svalbard archipelago., Generalised estimating equations and multivariate ordination models showed benthic macroinvertebrate diversity and abundance were influenced significantly by several environmental habitat variables. Rivers in non-glacierised basins typically supported more diverse and abundant communities than those in glacierised basins, most likely as a consequence of the warmer water temperature and less-disturbed habitat conditions associated with these systems., Consequently, shifts in water source contributions driven by changes in climate may alter environmental habitat conditions in Svalbard rivers and could lead to an increase in abundance and diversity among some freshwater macroinvertebrate communities. [ABSTRACT FROM AUTHOR]

Published
2014
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33. Water temperature dynamics in High Arctic river basins.

Author

Blaen, Phillip J., Hannah, David M., Brown, Lee E., and Milner, Alexander M.

Subjects
CLIMATE change, WATERSHEDS, SNOWMELT, WATER temperature, STREAM measurements
Abstract

Despite the high sensitivity of polar regions to climate change and the strong influence of temperature upon ecosystem processes, contemporary understanding of water temperature dynamics in Arctic river systems is limited. This research gap was addressed by exploring high-resolution water column thermal regimes for glacier-fed and non-glacial rivers at eight sites across Svalbard during the 2010 melt season. Mean water column temperatures in glacier-fed rivers (0.3-3.2 °C) were lowest and least variable near the glacier terminus but increased downstream (0.7-2.3 °C km-1). Non-glacial rivers, where discharge was sourced primarily from snowmelt runoff, were warmer (mean: 2.9-5.7 °C) and more variable, indicating increased water residence times in shallow alluvial zones and increased potential for atmospheric influence. Mean summer water temperature and the magnitude of daily thermal variation were similar to those of some Alaskan Arctic rivers but low at all sites when compared with alpine glacierized environments at lower latitudes. Thermal regimes were correlated strongly ( p < 0.01) with incoming short-wave radiation, air temperature, and river discharge. Principal drivers of thermal variability were inferred to be (i) water source (i.e. glacier melt, snowmelt, groundwater); (ii) exposure time to the atmosphere; (iii) prevailing meteorological conditions; (iv) river discharge; (v) runoff interaction with permafrost and buried ice; and (vi) basin-specific geomorphological features (e.g. channel morphology). These results provide insight into the potential changes in high-latitude river systems in the context of projected warming in polar regions. We hypothesize that warmer and more variable temperature regimes may prevail in the future as the proportion of bulk discharge sourced from glacial meltwater declines and rivers undergo a progressive shift towards snow water and groundwater sources. Importantly, such changes could have implications for aquatic species diversity and abundance and influence rates of ecosystem functioning in high-latitude river systems. Copyright © 2012 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published
2013
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34. Using recirculating flumes and a response surface model to investigate the role of hyporheic exchange and bacterial diversity on micropollutant half-lives

Author

Jaeger, Anna, Coll, Claudia, Posselt, Malte, Mechelke, Jonas, Rutere, Cyrus, Betterle, Andrea, Raza, Muhammad, Mehrtens, Anne, Meinikmann, Karin, Portmann, Andrea, Singh, Tanu, Blaen, Phillip J., Krause, Stefan, Horn, Marcus A., Hollender, Juliane, Benskin, Jonathan P., Sobek, Anna, and Lewandowski, Joerg

Subjects
Rivers, Stream flow, Surface properties, Amides, Decision making, Sugar substitutes, 6. Clean water, Dewey Decimal Classification::300 | Sozialwissenschaften, Soziologie, Anthropologie::330 | Wirtschaft::333 | Boden- und Energiewirtschaft::333,7 | Natürliche Ressourcen, Energie und Umwelt, Risk assessment
Abstract

Enhancing the understanding of the fate of wastewater-derived organic micropollutants in rivers is crucialto improve risk assessment, regulatory decision making and river management. Hyporheic exchange andsediment bacterial diversity are two factors gaining increasing importance as drivers for micropollutantdegradation, but are complex to study infield experiments and usually ignored in laboratory tests aimedto estimate environmental half-lives. Flume mesocosms are useful to investigate micropollutantdegradation processes, bridging the gap between thefield and batch experiments. However, few studieshave usedflumes in this context. We present a novel experimental setup using 20 recirculatingflumesand a response surface model to study the influence of hyporheic exchange and sediment bacterialdiversity on half-lives of the anti-epileptic drug carbamazepine (CBZ) and the artificial sweeteneracesulfame (ACS). The effect of bedform-induced hyporheic exchange was tested by three treatmentlevels differing in number of bedforms (0, 3 and 6). Three levels of sediment bacterial diversity wereobtained by diluting sediment from the River Erpe in Berlin, Germany, with sand (1 : 10, 1 : 1000 and1 : 100 000). Our results show that ACS half-lives were significantly influenced by sediment dilution andnumber of bedforms. Half-lives of CBZ were higher than ACS, and were significantly affected only by thesediment dilution variable, and thus by bacterial diversity. Our results show that (1) theflume-setup isa useful tool to study the fate of micropollutants in rivers, and that (2) higher hyporheic exchange andbacterial diversity in the sediment can increase the degradation of micropollutants in rivers.

35. Co-located contemporaneous mapping of morphological, hydrological, chemical, and biological conditions in a 5th-order mountain stream network, Oregon, USA

Author

Ward, Adam S., Zarnetske, Jay P., Baranov, Viktor, Blaen, Phillip J., Brekenfeld, Nicolai, Chu, Rosalie, Derelle, Romain, Drummond, Jennifer, Fleckenstein, Jan H., Garayburu-Caruso, Vanessa, Graham, Emily, Hannah, David, Harman, Ciaran J., Herzog, Skuyler, Hixson, Jase, Knapp, Julia, Krause, Stefan, Kurz, Marie J., Lewandowski, Jörg, Li, Angang, Martí, Eugènía, Miller, Melinda, Milner, Alexander M., Neil, Kerry, Orsini, Luisa, Packman, Aaron I., Plont, Stephen, Renteria, Lupita, Roche, Kevin, Royer, Todd, Schmadel, Noah M., Segura, Catalina, Stegen, James, Toyoda, Jason, Wells, Jacqueline, Wisnoski, Nathan I., and Wondzell, Steven M.

Subjects
15. Life on land, 6. Clean water
Abstract

A comprehensive set of measurements and calculated metrics describing physical, chemical, and biological conditions in the river corridor is presented. These data were collected in a catchment-wide, synoptic campaign in the H. J. Andrews Experimental Forest (Cascade Mountains, Oregon, USA) in summer 2016 during low-discharge conditions. Extensive characterization of 62 sites including surface water, hyporheic water, and streambed sediment was conducted spanning 1st- through 5th-order reaches in the river network. The objective of the sample design and data acquisition was to generate a novel data set to support scaling of river corridor processes across varying flows and morphologic forms present in a river network. The data are available at https://doi.org/10.4211/hs.f4484e0703f743c696c2e1f209abb842 (Ward, 2019)., Earth System Science Data, 11 (4), ISSN:1866-3516, ISSN:1866-3508

36. Spatial and temporal variation in river corridor exchange across a 5th-order mountain stream network

Author

Ward, Adam S., Wondzell, Steven M., Schmadel, Noah M., Herzog, Skuyler, Zarnetske, Jay P., Baranov, Viktor, Blaen, Phillip J., Brekenfeld, Nicolai, Chu, Rosalie, Derelle, Romain, Drummond, Jennifer, Fleckenstein, Jan H., Garayburu-Caruso, Vanessa, Graham, Emily, Hannah, David, Harman, Ciaran J., Hixson, Jase, Knapp, Julia L.A., Krause, Stefan, Kurz, Marie J., Lewandowski, Jörg, Li, Angang, Martí, Eugènía, Miller, Melinda, Milner, Alexander M., Neil, Kerry, Orsini, Luisa, Packman, Aaron I., Plont, Stephen, Renteria, Lupita, Roche, Kevin, Royer, Todd, Segura, Catalina, Stegen, James, Toyoda, Jason, Wells, Jacqueline, and Wisnoski, Nathan I.

Subjects
13. Climate action, 15. Life on land, 6. Clean water
Abstract

Although most field and modeling studies of river corridor exchange have been conducted at scales ranging from tens to hundreds of meters, results of these studies are used to predict their ecological and hydrological influences at the scale of river networks. Further complicating prediction, exchanges are expected to vary with hydrologic forcing and the local geomorphic setting. While we desire predictive power, we lack a complete spatiotemporal relationship relating discharge to the variation in geologic setting and hydrologic forcing that is expected across a river basin. Indeed, the conceptual model of Wondzell (2011) predicts systematic variation in river corridor exchange as a function of (1) variation in baseflow over time at a fixed location, (2) variation in discharge with location in the river network, and (3) local geomorphic setting. To test this conceptual model we conducted more than 60 solute tracer studies including a synoptic campaign in the 5th-order river network of the H. J. Andrews Experimental Forest (Oregon, USA) and replicate-in-time experiments in four watersheds. We interpret the data using a series of metrics describing river corridor exchange and solute transport, testing for consistent direction and magnitude of relationships relating these metrics to discharge and local geomorphic setting. We confirmed systematic decrease in river corridor exchange space through the river networks, from headwaters to the larger main stem. However, we did not find systematic variation with changes in discharge through time or with local geomorphic setting. While interpretation of our results is complicated by problems with the analytical methods, the results are sufficiently robust for us to conclude that space-for-time and time-for-space substitutions are not appropriate in our study system. Finally, we suggest two strategies that will improve the interpretability of tracer test results and help the hyporheic community develop robust datasets that will enable comparisons across multiple sites and/or discharge conditions., Hydrology and Earth System Sciences, 23 (12), ISSN:1027-5606, ISSN:1607-7938

37. Using recirculating flumes and a response surface model to investigate the role of hyporheic exchange and bacterial diversity on micropollutant half-lives

Author

Jaeger, Anna, Coll, Claudia, Posselt, Malte, Mechelke, Jonas, Rutere, Cyrus, Betterle, Andrea, Raza, Muhammad, Mehrtens, Anne, Meinikmann, Karin, Portmann, Andrea, Singh, Tanu, Blaen, Phillip J., Krause, Stefan, Horn, Marcus A., Hollender, Juliane, Benskin, Jonathan P., Sobek, Anna, and Lewandowski, Jörg

Subjects
human activities, 6. Clean water
Abstract

Enhancing the understanding of the fate of wastewater-derived organic micropollutants in rivers is crucial to improve risk assessment, regulatory decision making and river management. Hyporheic exchange and sediment bacterial diversity are two factors gaining increasing importance as drivers for micropollutant degradation, but are complex to study in field experiments and usually ignored in laboratory tests aimed to estimate environmental half-lives. Flume mesocosms are useful to investigate micropollutant degradation processes, bridging the gap between the field and batch experiments. However, few studies have used flumes in this context. We present a novel experimental setup using 20 recirculating flumes and a response surface model to study the influence of hyporheic exchange and sediment bacterial diversity on half-lives of the anti-epileptic drug carbamazepine (CBZ) and the artificial sweetener acesulfame (ACS). The effect of bedform-induced hyporheic exchange was tested by three treatment levels differing in number of bedforms (0, 3 and 6). Three levels of sediment bacterial diversity were obtained by diluting sediment from the River Erpe in Berlin, Germany, with sand (1 : 10, 1 : 1000 and 1 : 100 000). Our results show that ACS half-lives were significantly influenced by sediment dilution and number of bedforms. Half-lives of CBZ were higher than ACS, and were significantly affected only by the sediment dilution variable, and thus by bacterial diversity. Our results show that (1) the flume-setup is a useful tool to study the fate of micropollutants in rivers, and that (2) higher hyporheic exchange and bacterial diversity in the sediment can increase the degradation of micropollutants in rivers., Environmental Science: Processes & Impacts, 21 (12), ISSN:2050-7887, ISSN:2050-7895

38. Transformation of organic micropollutants along hyporheic flow in bedforms of river-simulating flumes

Author

Jaeger, Anna, Posselt, Malte, Schaper, Jonas L., Betterle, Andrea, Rutere, Cyrus, Coll, Claudia, Mechelke, Jonas, Raza, Muhammad, Meinikmann, Karin, Portmann, Andrea, Blaen, Phillip J., Horn, Marcus A., Krause, Stefan, and Lewandowski, Jörg

Subjects
6. Clean water
Abstract

Urban streams receive increasing loads of organic micropollutants from treated wastewaters. A comprehensive understanding of the in-stream fate of micropollutants is thus of high interest for water quality management. Bedforms induce pumping effects considerably contributing to whole stream hyporheic exchange and are hotspots of biogeochemical turnover processes. However, little is known about the transformation of micropollutants in such structures. In the present study, we set up recirculating flumes to examine the transformation of a set of micropollutants along single flowpaths in two triangular bedforms. We sampled porewater from four locations in the bedforms over 78 days and analysed the resulting concentration curves using the results of a hydrodynamic model in combination with a reactive transport model accounting for advection, dispersion, first-order removal and retardation. The four porewater sampling locations were positioned on individual flowpaths with median solute travel times ranging from 11.5 to 43.3 h as shown in a hydrodynamic model previously. Highest stability was estimated for hydrochlorothiazide on all flowpaths. Lowest detectable half-lives were estimated for sotalol (0.7 h) and sitagliptin (0.2 h) along the shortest flowpath. Also, venlafaxine, acesulfame, bezafibrate, irbesartan, valsartan, ibuprofen and naproxen displayed lower half-lives at shorter flowpaths in the first bedform. However, the behavior of many compounds in the second bedform deviated from expectations, where particularly transformation products, e.g. valsartan acid, showed high concentrations. Flowpath-specific behavior as observed for metformin or flume-specific behavior as observed for metoprolol acid, for instance, was attributed to potential small-scale or flume-scale heterogeneity of microbial community compositions, respectively. The results of the study indicate that the shallow hyporheic flow field and the small-scale heterogeneity of the microbial community are major controlling factors for the transformation of relevant micropollutants in river sediments., Scientific Reports, 11 (1), ISSN:2045-2322

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