Repeated high flows drive morphological change in rivers in recently deglaciated catchments

Lawrence J.B. Eagle; Jonathan L. Carrivick; Alexander M. Milner; Lee E. Brown; Megan J. Klaar

doi:10.1002/esp.5098

Repeated high flows drive morphological change in rivers in recently deglaciated catchments

Lawrence J.B. Eagle^*, Jonathan L. Carrivick, Alexander M. Milner, Lee E. Brown, Megan J. Klaar

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

4 Citations (Scopus)

4 Downloads (Pure)

Abstract

Climate change is decreasing glacier cover and increasing the frequency and magnitude of precipitation-driven high flows and floods in many regions of the world. Precipitation may become the dominant water source for river systems in recently deglaciated catchments, with major rainfall events driving significant changes in river channel morphology. Few studies, however, have examined river channel response to repeated precipitation-driven high flows. In this study, we measured the geomorphological condition of four low-order rivers in recently deglaciated catchments (70–210 years ice free) before and after a series of repeated precipitation-driven high flows during summer 2014. High flows drove substantial initial morphological change, with up to 75% change in baseflow channel planform position and active channel form change from pre- to post-high flow. Post-high flow years were associated with increased instream wood and geomorphological complexity at all but the youngest river. Channel changes were part of an active relaxation stage at all rivers, where channels continued to migrate, and complexity varied through time. Overall, these measurements permit us to propose a conceptual model of the role of geomorphologically effective high flows in the context of paraglacial adjustment theory. Specifically, we suggest that older rivers in recently deglaciated catchments can undergo a short-term (<10 years) increase in the rate of geomorphological development as a result of the recruitment of instream wood and channel migration during and following repeated precipitation-driven high flows. Enhancing our knowledge of these geomorphological and paraglacial processes in response to high flows is important for the effective management of riverine water and ecosystem resources in rapidly changing environments.

Original language	English
Pages (from-to)	1294-1310
Number of pages	17
Journal	Earth Surface Processes and Landforms
Volume	46
Issue number	7
Early online date	18 Feb 2021
DOIs	https://doi.org/10.1002/esp.5098
Publication status	Published - 15 Jun 2021

Bibliographical note

Funding Information:
We acknowledge the contribution of research assistants who have through the duration of this study provided important contributions to the delivery of this research. These individuals include Sophie Pearce, George Keough, Lewis Blake, Mike McDermott and Charlotte Willis. We thank the NPS at Glacier Bay for the logistical and field support. Principally we thank Captains Justin Smith, Deb Johnson and Todd Bruno for supporting field campaigns in the bay over the last 10 years. Research has been supported by funding from various bodies including NERC (GR9/2913, NE/E003729/1, NE/E004539/1, NE/E004148/1 and NE/M0174781/1), the Royal Society, the Universities of Birmingham, Leeds and Worcester, water@leeds and British Society for Geomorphology. Thanks are offered to PBA Applied Ecology Ltd. for LE's continued contribution. The authors have no conflicts of interest to declare.

Publisher Copyright:
© 2021 The Authors. Earth Surface Processes and Landforms published by John Wiley & Sons Ltd.

Keywords

ecosystem disturbance
floods
fluvial sediment transport
geomorphological development
instream wood
paraglacial adjustment
repeated high flow

ASJC Scopus subject areas

Geography, Planning and Development
Earth-Surface Processes
Earth and Planetary Sciences (miscellaneous)

UN SDGs

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

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10.1002/esp.5098Licence: Creative Commons: Attribution (CC BY)

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Cite this

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title = "Repeated high flows drive morphological change in rivers in recently deglaciated catchments",

abstract = "Climate change is decreasing glacier cover and increasing the frequency and magnitude of precipitation-driven high flows and floods in many regions of the world. Precipitation may become the dominant water source for river systems in recently deglaciated catchments, with major rainfall events driving significant changes in river channel morphology. Few studies, however, have examined river channel response to repeated precipitation-driven high flows. In this study, we measured the geomorphological condition of four low-order rivers in recently deglaciated catchments (70–210 years ice free) before and after a series of repeated precipitation-driven high flows during summer 2014. High flows drove substantial initial morphological change, with up to 75% change in baseflow channel planform position and active channel form change from pre- to post-high flow. Post-high flow years were associated with increased instream wood and geomorphological complexity at all but the youngest river. Channel changes were part of an active relaxation stage at all rivers, where channels continued to migrate, and complexity varied through time. Overall, these measurements permit us to propose a conceptual model of the role of geomorphologically effective high flows in the context of paraglacial adjustment theory. Specifically, we suggest that older rivers in recently deglaciated catchments can undergo a short-term (<10 years) increase in the rate of geomorphological development as a result of the recruitment of instream wood and channel migration during and following repeated precipitation-driven high flows. Enhancing our knowledge of these geomorphological and paraglacial processes in response to high flows is important for the effective management of riverine water and ecosystem resources in rapidly changing environments.",

keywords = "ecosystem disturbance, floods, fluvial sediment transport, geomorphological development, instream wood, paraglacial adjustment, repeated high flow",

author = "Eagle, {Lawrence J.B.} and Carrivick, {Jonathan L.} and Milner, {Alexander M.} and Brown, {Lee E.} and Klaar, {Megan J.}",

note = "Funding Information: We acknowledge the contribution of research assistants who have through the duration of this study provided important contributions to the delivery of this research. These individuals include Sophie Pearce, George Keough, Lewis Blake, Mike McDermott and Charlotte Willis. We thank the NPS at Glacier Bay for the logistical and field support. Principally we thank Captains Justin Smith, Deb Johnson and Todd Bruno for supporting field campaigns in the bay over the last 10 years. Research has been supported by funding from various bodies including NERC (GR9/2913, NE/E003729/1, NE/E004539/1, NE/E004148/1 and NE/M0174781/1), the Royal Society, the Universities of Birmingham, Leeds and Worcester, water@leeds and British Society for Geomorphology. Thanks are offered to PBA Applied Ecology Ltd. for LE's continued contribution. The authors have no conflicts of interest to declare. Publisher Copyright: {\textcopyright} 2021 The Authors. Earth Surface Processes and Landforms published by John Wiley & Sons Ltd.",

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AU - Eagle, Lawrence J.B.

AU - Carrivick, Jonathan L.

AU - Milner, Alexander M.

AU - Brown, Lee E.

AU - Klaar, Megan J.

N1 - Funding Information: We acknowledge the contribution of research assistants who have through the duration of this study provided important contributions to the delivery of this research. These individuals include Sophie Pearce, George Keough, Lewis Blake, Mike McDermott and Charlotte Willis. We thank the NPS at Glacier Bay for the logistical and field support. Principally we thank Captains Justin Smith, Deb Johnson and Todd Bruno for supporting field campaigns in the bay over the last 10 years. Research has been supported by funding from various bodies including NERC (GR9/2913, NE/E003729/1, NE/E004539/1, NE/E004148/1 and NE/M0174781/1), the Royal Society, the Universities of Birmingham, Leeds and Worcester, water@leeds and British Society for Geomorphology. Thanks are offered to PBA Applied Ecology Ltd. for LE's continued contribution. The authors have no conflicts of interest to declare. Publisher Copyright: © 2021 The Authors. Earth Surface Processes and Landforms published by John Wiley & Sons Ltd.

PY - 2021/6/15

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N2 - Climate change is decreasing glacier cover and increasing the frequency and magnitude of precipitation-driven high flows and floods in many regions of the world. Precipitation may become the dominant water source for river systems in recently deglaciated catchments, with major rainfall events driving significant changes in river channel morphology. Few studies, however, have examined river channel response to repeated precipitation-driven high flows. In this study, we measured the geomorphological condition of four low-order rivers in recently deglaciated catchments (70–210 years ice free) before and after a series of repeated precipitation-driven high flows during summer 2014. High flows drove substantial initial morphological change, with up to 75% change in baseflow channel planform position and active channel form change from pre- to post-high flow. Post-high flow years were associated with increased instream wood and geomorphological complexity at all but the youngest river. Channel changes were part of an active relaxation stage at all rivers, where channels continued to migrate, and complexity varied through time. Overall, these measurements permit us to propose a conceptual model of the role of geomorphologically effective high flows in the context of paraglacial adjustment theory. Specifically, we suggest that older rivers in recently deglaciated catchments can undergo a short-term (<10 years) increase in the rate of geomorphological development as a result of the recruitment of instream wood and channel migration during and following repeated precipitation-driven high flows. Enhancing our knowledge of these geomorphological and paraglacial processes in response to high flows is important for the effective management of riverine water and ecosystem resources in rapidly changing environments.

AB - Climate change is decreasing glacier cover and increasing the frequency and magnitude of precipitation-driven high flows and floods in many regions of the world. Precipitation may become the dominant water source for river systems in recently deglaciated catchments, with major rainfall events driving significant changes in river channel morphology. Few studies, however, have examined river channel response to repeated precipitation-driven high flows. In this study, we measured the geomorphological condition of four low-order rivers in recently deglaciated catchments (70–210 years ice free) before and after a series of repeated precipitation-driven high flows during summer 2014. High flows drove substantial initial morphological change, with up to 75% change in baseflow channel planform position and active channel form change from pre- to post-high flow. Post-high flow years were associated with increased instream wood and geomorphological complexity at all but the youngest river. Channel changes were part of an active relaxation stage at all rivers, where channels continued to migrate, and complexity varied through time. Overall, these measurements permit us to propose a conceptual model of the role of geomorphologically effective high flows in the context of paraglacial adjustment theory. Specifically, we suggest that older rivers in recently deglaciated catchments can undergo a short-term (<10 years) increase in the rate of geomorphological development as a result of the recruitment of instream wood and channel migration during and following repeated precipitation-driven high flows. Enhancing our knowledge of these geomorphological and paraglacial processes in response to high flows is important for the effective management of riverine water and ecosystem resources in rapidly changing environments.

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KW - floods

KW - fluvial sediment transport

KW - geomorphological development

KW - instream wood

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KW - repeated high flow

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Repeated high flows drive morphological change in rivers in recently deglaciated catchments

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

UN SDGs

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