Electrical imaging of hyporheic exchange from channel-spanning logjams

Includes bibliographical references. 2019 Spring. Human impacts such as timber harvesting, engineered channels, beaver removal, and urbanization can alter the inherent characteristics and features of streams, which affect their natural physical and chemical states. One such feature substantially dim...

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Main Author: Doughty, Megan
Other Authors: Singha, Kamini, Wohl, Ellen, Hogue, Terri S.
Format: Text
Language:English
Published: Colorado School of Mines. Arthur Lakes Library 2019
Subjects:
hydrology
logjam
hyporheic
electrical resistivity
Beaver Creek
Online Access:https://hdl.handle.net/11124/173062
id ftmountainschol:oai:mountainscholar.org:11124/173062
record_format openpolar
spelling ftmountainschol:oai:mountainscholar.org:11124/173062 2023-05-15T15:41:09+02:00 Electrical imaging of hyporheic exchange from channel-spanning logjams Doughty, Megan Singha, Kamini Wohl, Ellen Hogue, Terri S. 2019-06-14T15:39:22Z born digital masters theses application/pdf https://hdl.handle.net/11124/173062 English eng eng Colorado School of Mines. Arthur Lakes Library Doughty_mines_0052N_11728.pdf T 8719 https://hdl.handle.net/11124/173062 Copyright of the original work is retained by the author. hydrology logjam hyporheic electrical resistivity Text 2019 ftmountainschol 2022-03-07T21:21:16Z Includes bibliographical references. 2019 Spring. Human impacts such as timber harvesting, engineered channels, beaver removal, and urbanization can alter the inherent characteristics and features of streams, which affect their natural physical and chemical states. One such feature substantially diminished by anthropogenic changes is the development of blockages from fallen trees and loose wood in streams. These logjams increase hydraulic resistance and create hydraulic head gradients along the streambed that drive groundwater-surface water exchange. This exchange occurs in saturated sediment under and around a stream, called the hyporheic zone, where surface water and groundwater mix. Hyporheic exchange has an important influence on a stream’s ecosystem, because it transfers dissolved oxygen, solutes, and nutrients into the subsurface as well as mediates temperature fluctuations. Here, we focus on quantifying the changes in hyporheic exchange flow (HEF) due to channel-spanning logjams. Field measurements and numerical modeling using MODFLOW and MT3D were used in this study to explore logjam-induced hyporheic exchange. The traditional methods for characterizing HEF, such as in-stream and well monitoring, fail to capture the complex hyporheic processes because they only provide point measurements. Electrical resistivity imaging (ERI), a surface-based geophysical method, was used to monitor the transport of solutes into the hyporheic zone during an in-stream tracer test supplemented by in-stream monitoring. ERI provides spatial and temporal data on the distribution of subsurface bulk electrical resistivity. We ran ERI at two reaches in Little Beaver Creek, CO: one with a single logjam and the second at a control reach with no logjams. Our results show that 1) higher HEF occurred at the reach with a logjam than the one without, and that 2) higher discharge rates associated with spring snowmelt increase the extent and magnitude of HEF, while 3) lower flows may increase the residence time in the hyporheic zone. The numerical modeling in MODFLOW and MT3D supports the finding that logjams increase the extent and rate of HEF. This research has implications for quantifying the controls of natural stream heterogeneity, the transport of sediment, the health of the stream’s ecosystem, and improving stream restoration and conservation efforts. Text Beaver Creek Mountain Scholar (Digital Collections of Colorado and Wyoming)
institution Open Polar
collection Mountain Scholar (Digital Collections of Colorado and Wyoming)
op_collection_id ftmountainschol
language English
topic hydrology
logjam
hyporheic
electrical resistivity
spellingShingle hydrology
logjam
hyporheic
electrical resistivity
Doughty, Megan
Electrical imaging of hyporheic exchange from channel-spanning logjams
topic_facet hydrology
logjam
hyporheic
electrical resistivity
description Includes bibliographical references. 2019 Spring. Human impacts such as timber harvesting, engineered channels, beaver removal, and urbanization can alter the inherent characteristics and features of streams, which affect their natural physical and chemical states. One such feature substantially diminished by anthropogenic changes is the development of blockages from fallen trees and loose wood in streams. These logjams increase hydraulic resistance and create hydraulic head gradients along the streambed that drive groundwater-surface water exchange. This exchange occurs in saturated sediment under and around a stream, called the hyporheic zone, where surface water and groundwater mix. Hyporheic exchange has an important influence on a stream’s ecosystem, because it transfers dissolved oxygen, solutes, and nutrients into the subsurface as well as mediates temperature fluctuations. Here, we focus on quantifying the changes in hyporheic exchange flow (HEF) due to channel-spanning logjams. Field measurements and numerical modeling using MODFLOW and MT3D were used in this study to explore logjam-induced hyporheic exchange. The traditional methods for characterizing HEF, such as in-stream and well monitoring, fail to capture the complex hyporheic processes because they only provide point measurements. Electrical resistivity imaging (ERI), a surface-based geophysical method, was used to monitor the transport of solutes into the hyporheic zone during an in-stream tracer test supplemented by in-stream monitoring. ERI provides spatial and temporal data on the distribution of subsurface bulk electrical resistivity. We ran ERI at two reaches in Little Beaver Creek, CO: one with a single logjam and the second at a control reach with no logjams. Our results show that 1) higher HEF occurred at the reach with a logjam than the one without, and that 2) higher discharge rates associated with spring snowmelt increase the extent and magnitude of HEF, while 3) lower flows may increase the residence time in the hyporheic zone. The numerical modeling in MODFLOW and MT3D supports the finding that logjams increase the extent and rate of HEF. This research has implications for quantifying the controls of natural stream heterogeneity, the transport of sediment, the health of the stream’s ecosystem, and improving stream restoration and conservation efforts.
author2 Singha, Kamini
Wohl, Ellen
Hogue, Terri S.
format Text
author Doughty, Megan
author_facet Doughty, Megan
author_sort Doughty, Megan
title Electrical imaging of hyporheic exchange from channel-spanning logjams
title_short Electrical imaging of hyporheic exchange from channel-spanning logjams
title_full Electrical imaging of hyporheic exchange from channel-spanning logjams
title_fullStr Electrical imaging of hyporheic exchange from channel-spanning logjams
title_full_unstemmed Electrical imaging of hyporheic exchange from channel-spanning logjams
title_sort electrical imaging of hyporheic exchange from channel-spanning logjams
publisher Colorado School of Mines. Arthur Lakes Library
publishDate 2019
url https://hdl.handle.net/11124/173062
genre Beaver Creek
genre_facet Beaver Creek
op_relation Doughty_mines_0052N_11728.pdf
T 8719
https://hdl.handle.net/11124/173062
op_rights Copyright of the original work is retained by the author.
_version_ 1766374010490191872

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