Impact of hydrogeological factors on groundwater salinization due to ocean-surge inundation

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autorschaft

  • Jie Yang
  • Huichen Zhang
  • Xuan Yu
  • Thomas Graf
  • Holly A. Michael

Organisationseinheiten

Externe Organisationen

  • Helmholtz Zentrum München - Deutsches Forschungszentrum für Gesundheit und Umwelt
  • University of Delaware
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Details

OriginalspracheEnglisch
Seiten (von - bis)423-434
Seitenumfang12
FachzeitschriftAdvances in water resources
Jahrgang111
Frühes Online-Datum20 Nov. 2017
PublikationsstatusVeröffentlicht - Jan. 2018

Abstract

Ocean surges cause seawater inundation of coastal inland areas. Subsequently, seawater infiltrates into coastal aquifers and threatens the fresh groundwater resource. The severity of resulting salinization can be affected by hydrogeological factors including aquifer properties and hydrologic conditions, however, little research has been done to assess these effects. To understand the impacts of hydrogeological factors on groundwater salinization, we numerically simulated an ocean-surge inundation event on a two-dimensional conceptual coastal aquifer using a coupled surface-subsurface approach. We varied model permeability (including anisotropy), inland hydraulic gradient, and recharge rate. Three salinization-assessment indicators were developed, based on flushing time, depth of salt penetration, and a combination of the two, weighted flushing time, with which the impact of hydrogeological factors on groundwater vulnerability to salinization were quantitatively assessed. The vulnerability of coastal aquifers increases with increasing isotropic permeability. Low horizontal permeability (kx) and high vertical permeability (kz) lead to high aquifer vulnerability, and high kx and low kz lead to low aquifer vulnerability. Vulnerability decreases with increasing groundwater hydraulic gradient and increasing recharge rate. Additionally, coastal aquifers with a low recharge rate (R ≤ 300 mm yr−1) may be highly vulnerable to ocean-surge inundation. This study shows how the newly introduced indicators can be used to quantitatively assess coastal aquifer vulnerability. The results are important for global vulnerability assessment of coastal aquifers to ocean-surge inundation.

ASJC Scopus Sachgebiete

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Impact of hydrogeological factors on groundwater salinization due to ocean-surge inundation. / Yang, Jie; Zhang, Huichen; Yu, Xuan et al.
in: Advances in water resources, Jahrgang 111, 01.2018, S. 423-434.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Yang J, Zhang H, Yu X, Graf T, Michael HA. Impact of hydrogeological factors on groundwater salinization due to ocean-surge inundation. Advances in water resources. 2018 Jan;111:423-434. Epub 2017 Nov 20. doi: 10.1016/j.advwatres.2017.11.017
Yang, Jie ; Zhang, Huichen ; Yu, Xuan et al. / Impact of hydrogeological factors on groundwater salinization due to ocean-surge inundation. in: Advances in water resources. 2018 ; Jahrgang 111. S. 423-434.
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title = "Impact of hydrogeological factors on groundwater salinization due to ocean-surge inundation",
abstract = "Ocean surges cause seawater inundation of coastal inland areas. Subsequently, seawater infiltrates into coastal aquifers and threatens the fresh groundwater resource. The severity of resulting salinization can be affected by hydrogeological factors including aquifer properties and hydrologic conditions, however, little research has been done to assess these effects. To understand the impacts of hydrogeological factors on groundwater salinization, we numerically simulated an ocean-surge inundation event on a two-dimensional conceptual coastal aquifer using a coupled surface-subsurface approach. We varied model permeability (including anisotropy), inland hydraulic gradient, and recharge rate. Three salinization-assessment indicators were developed, based on flushing time, depth of salt penetration, and a combination of the two, weighted flushing time, with which the impact of hydrogeological factors on groundwater vulnerability to salinization were quantitatively assessed. The vulnerability of coastal aquifers increases with increasing isotropic permeability. Low horizontal permeability (kx) and high vertical permeability (kz) lead to high aquifer vulnerability, and high kx and low kz lead to low aquifer vulnerability. Vulnerability decreases with increasing groundwater hydraulic gradient and increasing recharge rate. Additionally, coastal aquifers with a low recharge rate (R ≤ 300 mm yr−1) may be highly vulnerable to ocean-surge inundation. This study shows how the newly introduced indicators can be used to quantitatively assess coastal aquifer vulnerability. The results are important for global vulnerability assessment of coastal aquifers to ocean-surge inundation.",
keywords = "Coastal aquifer, Hydrogeological characteristics, Ocean surge, Salinization",
author = "Jie Yang and Huichen Zhang and Xuan Yu and Thomas Graf and Michael, {Holly A.}",
note = "Funding information: This research was supported by the Deutsche Forschungsgemeinschaft (DFG) under grant number GR 3463/2-1 and by the US National Science Foundation (NSF) EPSCoR grant IIA-1301765. This research was initiated while Jie Yang was a visiting scholar at the University of Delaware and completed at Leibniz Universit{\"a}t Hannover. Assistance from these institutes is appreciated.",
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Download

TY - JOUR

T1 - Impact of hydrogeological factors on groundwater salinization due to ocean-surge inundation

AU - Yang, Jie

AU - Zhang, Huichen

AU - Yu, Xuan

AU - Graf, Thomas

AU - Michael, Holly A.

N1 - Funding information: This research was supported by the Deutsche Forschungsgemeinschaft (DFG) under grant number GR 3463/2-1 and by the US National Science Foundation (NSF) EPSCoR grant IIA-1301765. This research was initiated while Jie Yang was a visiting scholar at the University of Delaware and completed at Leibniz Universität Hannover. Assistance from these institutes is appreciated.

PY - 2018/1

Y1 - 2018/1

N2 - Ocean surges cause seawater inundation of coastal inland areas. Subsequently, seawater infiltrates into coastal aquifers and threatens the fresh groundwater resource. The severity of resulting salinization can be affected by hydrogeological factors including aquifer properties and hydrologic conditions, however, little research has been done to assess these effects. To understand the impacts of hydrogeological factors on groundwater salinization, we numerically simulated an ocean-surge inundation event on a two-dimensional conceptual coastal aquifer using a coupled surface-subsurface approach. We varied model permeability (including anisotropy), inland hydraulic gradient, and recharge rate. Three salinization-assessment indicators were developed, based on flushing time, depth of salt penetration, and a combination of the two, weighted flushing time, with which the impact of hydrogeological factors on groundwater vulnerability to salinization were quantitatively assessed. The vulnerability of coastal aquifers increases with increasing isotropic permeability. Low horizontal permeability (kx) and high vertical permeability (kz) lead to high aquifer vulnerability, and high kx and low kz lead to low aquifer vulnerability. Vulnerability decreases with increasing groundwater hydraulic gradient and increasing recharge rate. Additionally, coastal aquifers with a low recharge rate (R ≤ 300 mm yr−1) may be highly vulnerable to ocean-surge inundation. This study shows how the newly introduced indicators can be used to quantitatively assess coastal aquifer vulnerability. The results are important for global vulnerability assessment of coastal aquifers to ocean-surge inundation.

AB - Ocean surges cause seawater inundation of coastal inland areas. Subsequently, seawater infiltrates into coastal aquifers and threatens the fresh groundwater resource. The severity of resulting salinization can be affected by hydrogeological factors including aquifer properties and hydrologic conditions, however, little research has been done to assess these effects. To understand the impacts of hydrogeological factors on groundwater salinization, we numerically simulated an ocean-surge inundation event on a two-dimensional conceptual coastal aquifer using a coupled surface-subsurface approach. We varied model permeability (including anisotropy), inland hydraulic gradient, and recharge rate. Three salinization-assessment indicators were developed, based on flushing time, depth of salt penetration, and a combination of the two, weighted flushing time, with which the impact of hydrogeological factors on groundwater vulnerability to salinization were quantitatively assessed. The vulnerability of coastal aquifers increases with increasing isotropic permeability. Low horizontal permeability (kx) and high vertical permeability (kz) lead to high aquifer vulnerability, and high kx and low kz lead to low aquifer vulnerability. Vulnerability decreases with increasing groundwater hydraulic gradient and increasing recharge rate. Additionally, coastal aquifers with a low recharge rate (R ≤ 300 mm yr−1) may be highly vulnerable to ocean-surge inundation. This study shows how the newly introduced indicators can be used to quantitatively assess coastal aquifer vulnerability. The results are important for global vulnerability assessment of coastal aquifers to ocean-surge inundation.

KW - Coastal aquifer

KW - Hydrogeological characteristics

KW - Ocean surge

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