Coastal groundwater model calibration using filtered and amplified hydraulic information retained in the freshwater–saltwater interface Postprint

Coastal groundwater flow is driven by an interplay between terrestrial and marine forcings. One of the distinguishing features in these settings is the formation of a freshwater lens due to the density difference between fresh and saline groundwater. The present study uses data collected on Sable Is...

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Published in:Hydrogeology Journal
Main Authors: Pavlovksii, Igor, Cantelon, Julia A., Kurylyk, Barret L.
Format: Article in Journal/Newspaper
Language:unknown
Published: Springer 2023
Subjects:
Online Access:http://hdl.handle.net/10222/82726
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spelling ftdalhouse:oai:DalSpace.library.dal.ca:10222/82726 2023-08-20T04:08:48+02:00 Coastal groundwater model calibration using filtered and amplified hydraulic information retained in the freshwater–saltwater interface Postprint Pavlovksii, Igor Cantelon, Julia A. Kurylyk, Barret L. 2023-07-25T18:38:47Z http://hdl.handle.net/10222/82726 unknown Springer Hydrogeology Journal Published Version: Pavlovskii I, Cantelon JA, Kurylyk BL. 2022. Coastal groundwater model calibration using filtered and amplified hydraulic information retained in the freshwater-saltwater interface, Hydrogeology Journal, 30, 1551–1567, DOI:10.1007/s10040-022-02510-8. http://hdl.handle.net/10222/82726 Article 2023 ftdalhouse https://doi.org/10.1007/s10040-022-02510-8 2023-07-29T23:11:41Z Coastal groundwater flow is driven by an interplay between terrestrial and marine forcings. One of the distinguishing features in these settings is the formation of a freshwater lens due to the density difference between fresh and saline groundwater. The present study uses data collected on Sable Island, Canada—a remote sand island in the northwest Atlantic Ocean—to highlight the potential of exploiting freshwater lens geometry for calibration of numerical groundwater flow models in coastal settings. Three numerical three-dimensional variable-density groundwater flow models were constructed for different segments of the island, with only one model calibrated using the freshwater–saltwater interface derived from an electromagnetic geophysical survey. The other two (uncalibrated) models with the same parameterisation as the calibrated model successfully reproduced the interpreted interface depth and location of freshwater ponds at different parts of the island. The successful numerical model calibration, based solely on the geophysically derived interface depth, is enabled by the interface acting as an amplified version of the water table, which reduces the relative impact of the interpreted depth uncertainty. Furthermore, the freshwater–saltwater interface is far more inertial than the water table, making it less sensitive to short-term forcings. Such “noise-filtering” behaviour enables the use of the freshwater–saltwater interface for calibration even in dynamic set- tings where selection of representative groundwater heads is challenging. The completed models provide insights into island freshwater lens behaviour and highlight the role of periodic beach inundation and wave overheight in driving short-term water-table variability, despite their limited impact on the interface depth. Article in Journal/Newspaper Northwest Atlantic Dalhousie University: DalSpace Institutional Repository Canada Hydrogeology Journal 30 5 1551 1567
institution Open Polar
collection Dalhousie University: DalSpace Institutional Repository
op_collection_id ftdalhouse
language unknown
description Coastal groundwater flow is driven by an interplay between terrestrial and marine forcings. One of the distinguishing features in these settings is the formation of a freshwater lens due to the density difference between fresh and saline groundwater. The present study uses data collected on Sable Island, Canada—a remote sand island in the northwest Atlantic Ocean—to highlight the potential of exploiting freshwater lens geometry for calibration of numerical groundwater flow models in coastal settings. Three numerical three-dimensional variable-density groundwater flow models were constructed for different segments of the island, with only one model calibrated using the freshwater–saltwater interface derived from an electromagnetic geophysical survey. The other two (uncalibrated) models with the same parameterisation as the calibrated model successfully reproduced the interpreted interface depth and location of freshwater ponds at different parts of the island. The successful numerical model calibration, based solely on the geophysically derived interface depth, is enabled by the interface acting as an amplified version of the water table, which reduces the relative impact of the interpreted depth uncertainty. Furthermore, the freshwater–saltwater interface is far more inertial than the water table, making it less sensitive to short-term forcings. Such “noise-filtering” behaviour enables the use of the freshwater–saltwater interface for calibration even in dynamic set- tings where selection of representative groundwater heads is challenging. The completed models provide insights into island freshwater lens behaviour and highlight the role of periodic beach inundation and wave overheight in driving short-term water-table variability, despite their limited impact on the interface depth.
format Article in Journal/Newspaper
author Pavlovksii, Igor
Cantelon, Julia A.
Kurylyk, Barret L.
spellingShingle Pavlovksii, Igor
Cantelon, Julia A.
Kurylyk, Barret L.
Coastal groundwater model calibration using filtered and amplified hydraulic information retained in the freshwater–saltwater interface Postprint
author_facet Pavlovksii, Igor
Cantelon, Julia A.
Kurylyk, Barret L.
author_sort Pavlovksii, Igor
title Coastal groundwater model calibration using filtered and amplified hydraulic information retained in the freshwater–saltwater interface Postprint
title_short Coastal groundwater model calibration using filtered and amplified hydraulic information retained in the freshwater–saltwater interface Postprint
title_full Coastal groundwater model calibration using filtered and amplified hydraulic information retained in the freshwater–saltwater interface Postprint
title_fullStr Coastal groundwater model calibration using filtered and amplified hydraulic information retained in the freshwater–saltwater interface Postprint
title_full_unstemmed Coastal groundwater model calibration using filtered and amplified hydraulic information retained in the freshwater–saltwater interface Postprint
title_sort coastal groundwater model calibration using filtered and amplified hydraulic information retained in the freshwater–saltwater interface postprint
publisher Springer
publishDate 2023
url http://hdl.handle.net/10222/82726
geographic Canada
geographic_facet Canada
genre Northwest Atlantic
genre_facet Northwest Atlantic
op_relation Hydrogeology Journal
Published Version: Pavlovskii I, Cantelon JA, Kurylyk BL. 2022. Coastal groundwater model calibration using filtered and amplified hydraulic information retained in the freshwater-saltwater interface, Hydrogeology Journal, 30, 1551–1567, DOI:10.1007/s10040-022-02510-8.
http://hdl.handle.net/10222/82726
op_doi https://doi.org/10.1007/s10040-022-02510-8
container_title Hydrogeology Journal
container_volume 30
container_issue 5
container_start_page 1551
op_container_end_page 1567
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