Organizational principles of hyporheic exchange flow and biogeochemical cycling in river networks across scales

Stefan Krause; Benjamin W. Abbott; Viktor Baranov; Susana Bernal; Phillip Blaen; Thibault Datry; Jennifer Drummond; Jan H. Fleckenstein; Jesus Gomez Velez; David M. Hannah; Julia L. A. Knapp; Marie Kurz; Jörg Lewandowski; Eugènia Martí; Clara Mendoza‐lera; Alexander Milner; Aaron Packman; Gilles Pinay; Adam S. Ward; Jay P. Zarnetzke

doi:10.1029/2021WR029771

Organizational principles of hyporheic exchange flow and biogeochemical cycling in river networks across scales

Stefan Krause, Benjamin W. Abbott, Viktor Baranov, Susana Bernal, Phillip Blaen, Thibault Datry, Jennifer Drummond, Jan H. Fleckenstein, Jesus Gomez Velez, David M. Hannah, Julia L. A. Knapp, Marie Kurz, Jörg Lewandowski, Eugènia Martí, Clara Mendoza‐lera, Alexander Milner, Aaron Packman, Gilles Pinay, Adam S. Ward, Jay P. Zarnetzke

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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.

Original language	English
Article number	e2021WR029771
Journal	Water Resources Research
Volume	58
Issue number	3
Early online date	11 Feb 2022
DOIs	https://doi.org/10.1029/2021WR029771 https://doi.org/10.1029/2021WR029771
Publication status	Published - 1 Mar 2022

Bibliographical note

Funding Information:
This article is based on discussion stimulated throughout several large group experiments funded by the Leverhulme Trust International Network Grant () and the HORIZON 2020‐PEOPLE‐2016‐RISE project HiFreq (). The work of Stefan Krause and David M. Hannah has been funded through NERC NE/L003872/1 and through the UNESCO UniTwin network: Ecohydrological Interfaces and the Birmingham Institute of Global Innovation. Aaron Packman was supported by United States National Science Foundation (NSF) award number EAR‐1734300. Adam S. Ward was supported by NSF Award EAR 1652293, Department of Energy award DE‐SC0019377, the Burnell and Barbara Fischer Faculty Fellowship at Indiana University, and the University of Birmingham’s Institute for Advanced Studies. This research was sponsored by the Office of Biological and Environmental Research within the Office of Science of the U.S. Department of Energy (DOE), as part of the Environmental System Science supported Critical Interfaces Science Focus Area project at the Oak Ridge National Laboratory (ORNL). Where rivers, groundwater and disciplines meet: a hyporheic research network Smart high‐frequency environmental sensor networks for quantifying non‐linear hydrological process dynamics across spatial scales

Funding Information:
This article is based on discussion stimulated throughout several large group experiments funded by the Leverhulme Trust International Network Grant (Where rivers, groundwater and disciplines meet: a hyporheic research network) and the HORIZON 2020-PEOPLE-2016-RISE project HiFreq (Smart high-frequency environmental sensor networks for quantifying non-linear hydrological process dynamics across spatial scales). The work of Stefan Krause and David M. Hannah has been funded through NERC NE/L003872/1 and through the UNESCO UniTwin network: Ecohydrological Interfaces and the Birmingham Institute of Global Innovation. Aaron Packman was supported by United States National Science Foundation (NSF) award number EAR-1734300. Adam S. Ward was supported by NSF Award EAR 1652293, Department of Energy award DE-SC0019377, the Burnell and Barbara Fischer Faculty Fellowship at Indiana University, and the University of Birmingham?s Institute for Advanced Studies. This research was sponsored by the Office of Biological and Environmental Research within the Office of Science of the U.S. Department of Energy (DOE), as part of the Environmental System Science supported Critical Interfaces Science Focus Area project at the Oak Ridge National Laboratory (ORNL).

Publisher Copyright:
© 2022. The Authors.

Keywords

biogeochemical cycling
ecohydrological interfaces
ecological controls
hyporheic exchange flow
hyporheic zone
landscape organizational principles

ASJC Scopus subject areas

Water Science and Technology

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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https://onlinelibrary.wiley.com/doi/10.1029/2021WR029771

Large woody debris - A river restoration panacea for streambed nitrate attenuation?
Hannah, D., Krause, S. & Windridge, D.
Natural Environment Research Council
31/05/14 → 28/02/18
Project: Research Councils

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Krause, S., Abbott, B. W., Baranov, V., Bernal, S., Blaen, P., Datry, T., Drummond, J., Fleckenstein, J. H., Velez, J. G., Hannah, D. M., Knapp, J. L. A., Kurz, M., Lewandowski, J., Martí, E., Mendoza‐lera, C., Milner, A., Packman, A., Pinay, G., Ward, A. S., & Zarnetzke, J. P. (2022). Organizational principles of hyporheic exchange flow and biogeochemical cycling in river networks across scales. Water Resources Research, 58(3), Article e2021WR029771. Advance online publication. https://doi.org/10.1029/2021WR029771, https://doi.org/10.1029/2021WR029771

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title = "Organizational principles of hyporheic exchange flow and biogeochemical cycling in river networks across scales",

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.",

keywords = "biogeochemical cycling, ecohydrological interfaces, ecological controls, hyporheic exchange flow, hyporheic zone, landscape organizational principles",

author = "Stefan Krause and Abbott, {Benjamin W.} and Viktor Baranov and Susana Bernal and Phillip Blaen and Thibault Datry and Jennifer Drummond and Fleckenstein, {Jan H.} and Velez, {Jesus Gomez} and Hannah, {David M.} and Knapp, {Julia L. A.} and Marie Kurz and J{\"o}rg Lewandowski and Eug{\`e}nia Mart{\'i} and Clara Mendoza‐lera and Alexander Milner and Aaron Packman and Gilles Pinay and Ward, {Adam S.} and Zarnetzke, {Jay P.}",

note = "Funding Information: This article is based on discussion stimulated throughout several large group experiments funded by the Leverhulme Trust International Network Grant () and the HORIZON 2020‐PEOPLE‐2016‐RISE project HiFreq (). The work of Stefan Krause and David M. Hannah has been funded through NERC NE/L003872/1 and through the UNESCO UniTwin network: Ecohydrological Interfaces and the Birmingham Institute of Global Innovation. Aaron Packman was supported by United States National Science Foundation (NSF) award number EAR‐1734300. Adam S. Ward was supported by NSF Award EAR 1652293, Department of Energy award DE‐SC0019377, the Burnell and Barbara Fischer Faculty Fellowship at Indiana University, and the University of Birmingham{\textquoteright}s Institute for Advanced Studies. This research was sponsored by the Office of Biological and Environmental Research within the Office of Science of the U.S. Department of Energy (DOE), as part of the Environmental System Science supported Critical Interfaces Science Focus Area project at the Oak Ridge National Laboratory (ORNL). Where rivers, groundwater and disciplines meet: a hyporheic research network Smart high‐frequency environmental sensor networks for quantifying non‐linear hydrological process dynamics across spatial scales Funding Information: This article is based on discussion stimulated throughout several large group experiments funded by the Leverhulme Trust International Network Grant (Where rivers, groundwater and disciplines meet: a hyporheic research network) and the HORIZON 2020-PEOPLE-2016-RISE project HiFreq (Smart high-frequency environmental sensor networks for quantifying non-linear hydrological process dynamics across spatial scales). The work of Stefan Krause and David M. Hannah has been funded through NERC NE/L003872/1 and through the UNESCO UniTwin network: Ecohydrological Interfaces and the Birmingham Institute of Global Innovation. Aaron Packman was supported by United States National Science Foundation (NSF) award number EAR-1734300. Adam S. Ward was supported by NSF Award EAR 1652293, Department of Energy award DE-SC0019377, the Burnell and Barbara Fischer Faculty Fellowship at Indiana University, and the University of Birmingham?s Institute for Advanced Studies. This research was sponsored by the Office of Biological and Environmental Research within the Office of Science of the U.S. Department of Energy (DOE), as part of the Environmental System Science supported Critical Interfaces Science Focus Area project at the Oak Ridge National Laboratory (ORNL). Publisher Copyright: {\textcopyright} 2022. The Authors.",

year = "2022",

month = mar,

day = "1",

doi = "10.1029/2021WR029771",

language = "English",

volume = "58",

journal = "Water Resources Research",

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Krause, S, Abbott, BW, Baranov, V, Bernal, S, Blaen, P, Datry, T, Drummond, J, Fleckenstein, JH, Velez, JG, Hannah, DM, Knapp, JLA, Kurz, M, Lewandowski, J, Martí, E, Mendoza‐lera, C, Milner, A, Packman, A, Pinay, G, Ward, AS & Zarnetzke, JP 2022, 'Organizational principles of hyporheic exchange flow and biogeochemical cycling in river networks across scales', Water Resources Research, vol. 58, no. 3, e2021WR029771. https://doi.org/10.1029/2021WR029771, https://doi.org/10.1029/2021WR029771

TY - JOUR

T1 - Organizational principles of hyporheic exchange flow and biogeochemical cycling in river networks across scales

AU - Krause, Stefan

AU - Abbott, Benjamin W.

AU - Baranov, Viktor

AU - Bernal, Susana

AU - Blaen, Phillip

AU - Datry, Thibault

AU - Drummond, Jennifer

AU - Fleckenstein, Jan H.

AU - Velez, Jesus Gomez

AU - Hannah, David M.

AU - Knapp, Julia L. A.

AU - Kurz, Marie

AU - Lewandowski, Jörg

AU - Martí, Eugènia

AU - Mendoza‐lera, Clara

AU - Milner, Alexander

AU - Packman, Aaron

AU - Pinay, Gilles

AU - Ward, Adam S.

AU - Zarnetzke, Jay P.

N1 - Funding Information: This article is based on discussion stimulated throughout several large group experiments funded by the Leverhulme Trust International Network Grant () and the HORIZON 2020‐PEOPLE‐2016‐RISE project HiFreq (). The work of Stefan Krause and David M. Hannah has been funded through NERC NE/L003872/1 and through the UNESCO UniTwin network: Ecohydrological Interfaces and the Birmingham Institute of Global Innovation. Aaron Packman was supported by United States National Science Foundation (NSF) award number EAR‐1734300. Adam S. Ward was supported by NSF Award EAR 1652293, Department of Energy award DE‐SC0019377, the Burnell and Barbara Fischer Faculty Fellowship at Indiana University, and the University of Birmingham’s Institute for Advanced Studies. This research was sponsored by the Office of Biological and Environmental Research within the Office of Science of the U.S. Department of Energy (DOE), as part of the Environmental System Science supported Critical Interfaces Science Focus Area project at the Oak Ridge National Laboratory (ORNL). Where rivers, groundwater and disciplines meet: a hyporheic research network Smart high‐frequency environmental sensor networks for quantifying non‐linear hydrological process dynamics across spatial scales Funding Information: This article is based on discussion stimulated throughout several large group experiments funded by the Leverhulme Trust International Network Grant (Where rivers, groundwater and disciplines meet: a hyporheic research network) and the HORIZON 2020-PEOPLE-2016-RISE project HiFreq (Smart high-frequency environmental sensor networks for quantifying non-linear hydrological process dynamics across spatial scales). The work of Stefan Krause and David M. Hannah has been funded through NERC NE/L003872/1 and through the UNESCO UniTwin network: Ecohydrological Interfaces and the Birmingham Institute of Global Innovation. Aaron Packman was supported by United States National Science Foundation (NSF) award number EAR-1734300. Adam S. Ward was supported by NSF Award EAR 1652293, Department of Energy award DE-SC0019377, the Burnell and Barbara Fischer Faculty Fellowship at Indiana University, and the University of Birmingham?s Institute for Advanced Studies. This research was sponsored by the Office of Biological and Environmental Research within the Office of Science of the U.S. Department of Energy (DOE), as part of the Environmental System Science supported Critical Interfaces Science Focus Area project at the Oak Ridge National Laboratory (ORNL). Publisher Copyright: © 2022. The Authors.

PY - 2022/3/1

Y1 - 2022/3/1

N2 - 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.

AB - 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.

KW - biogeochemical cycling

KW - ecohydrological interfaces

KW - ecological controls

KW - hyporheic exchange flow

KW - hyporheic zone

KW - landscape organizational principles

UR - http://www.scopus.com/inward/record.url?scp=85127232440&partnerID=8YFLogxK

U2 - 10.1029/2021WR029771

DO - 10.1029/2021WR029771

M3 - Review article

SN - 0043-1397

VL - 58

JO - Water Resources Research

JF - Water Resources Research

IS - 3

M1 - e2021WR029771

ER -

Organizational principles of hyporheic exchange flow and biogeochemical cycling in river networks across scales

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

UN SDGs

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Large woody debris - A river restoration panacea for streambed nitrate attenuation?

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