Impact of inland boundary conditions on seawater intrusion modeling in stratified coastal aquifers under sea-level rise

Yuzheng Liu; Bojun Li; Wenjin Song; Yu He; Quan Guo; Minjae Kim; Saubhagya Singh Rathore; Jian Luo

doi:10.1016/j.jhydrol.2025.134193

Impact of inland boundary conditions on seawater intrusion modeling in stratified coastal aquifers under sea-level rise

Yuzheng Liu
, Bojun Li
, Wenjin Song
, Yu He
, Quan Guo
, Minjae Kim
, Saubhagya Singh Rathore
, Jian Luo

Watershed Systems Modeling

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

Abstract

This study systematically examines the impact of inland boundary conditions on seawater intrusion modeling in general stratified coastal aquifers under sea-level rise (SLR). We derived analytical solutions for seawater wedge toe positions in stratified aquifers with general head boundary (GHB) conditions and compiled solutions for constant head boundary (CHB), constant flux boundary (CFB), and GHB conditions in both homogeneous and stratified aquifers. Additionally, we introduced the concept of equivalent boundary conditions and developed equations to ensure consistent steady-state toe positions across different boundary types. Unlike previous studies focusing on specific layering configurations, we conducted a comprehensive sensitivity analysis of seawater intrusion in general stratified aquifers using transmissivity centroid elevation (TCE). Our results show that SLR generally exacerbates seawater intrusion, with unconfined aquifers exhibiting higher sensitivity across all boundary conditions. Among boundary types, CHB conditions were the most sensitive to SLR, CFB the least, and GHB showed an intermediate response depending on its distance from the model boundary. Furthermore, seawater intrusion increases with the TCE of the stratified aquifer under SLR, suggesting that high-permeability or preferential flow layers near the surface amplify the impact of SLR. These findings emphasize the importance of selecting appropriate boundary conditions when evaluating SLR-driven seawater intrusion in stratified coastal aquifers.

Original language	English
Article number	134193
Journal	Journal of Hydrology
Volume	663
DOIs	https://doi.org/10.1016/j.jhydrol.2025.134193
State	Published - Dec 2025

Funding

Note to publisher: This manuscript has been co-authored by staff from UT-Battelle, LLC, under contract DE-AC05-00OR22725 with the US Department of Energy (DOE). The US government retains and the publisher, by accepting the article for publication, acknowledges that the US government retains a nonexclusive, paid-up, irrevocable, worldwide license to publish or reproduce the published form of this manuscript, or allow others to do so, for US government purposes. DOE will provide public access to these results of federally sponsored research in accordance with the DOE Public Access Plan ( http://energy.gov/downloads/doe-public- access-plan). We thank the Editor, Associate Editor, and three anonymous reviewers for their constructive feedback. S.S.R. acknowledges support from the U.S. Department of Energy , Office of Science , Biological and Environmental Research program, through the Southeast Texas Urban Integrated Field Laboratory project.

Keywords

Boundary condition
General head boundary
Sea-level rise
Seawater intrusion
Stratified aquifer

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10.1016/j.jhydrol.2025.134193

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title = "Impact of inland boundary conditions on seawater intrusion modeling in stratified coastal aquifers under sea-level rise",

abstract = "This study systematically examines the impact of inland boundary conditions on seawater intrusion modeling in general stratified coastal aquifers under sea-level rise (SLR). We derived analytical solutions for seawater wedge toe positions in stratified aquifers with general head boundary (GHB) conditions and compiled solutions for constant head boundary (CHB), constant flux boundary (CFB), and GHB conditions in both homogeneous and stratified aquifers. Additionally, we introduced the concept of equivalent boundary conditions and developed equations to ensure consistent steady-state toe positions across different boundary types. Unlike previous studies focusing on specific layering configurations, we conducted a comprehensive sensitivity analysis of seawater intrusion in general stratified aquifers using transmissivity centroid elevation (TCE). Our results show that SLR generally exacerbates seawater intrusion, with unconfined aquifers exhibiting higher sensitivity across all boundary conditions. Among boundary types, CHB conditions were the most sensitive to SLR, CFB the least, and GHB showed an intermediate response depending on its distance from the model boundary. Furthermore, seawater intrusion increases with the TCE of the stratified aquifer under SLR, suggesting that high-permeability or preferential flow layers near the surface amplify the impact of SLR. These findings emphasize the importance of selecting appropriate boundary conditions when evaluating SLR-driven seawater intrusion in stratified coastal aquifers.",

keywords = "Boundary condition, General head boundary, Sea-level rise, Seawater intrusion, Stratified aquifer",

author = "Yuzheng Liu and Bojun Li and Wenjin Song and Yu He and Quan Guo and Minjae Kim and Rathore, \{Saubhagya Singh\} and Jian Luo",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s)",

year = "2025",

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doi = "10.1016/j.jhydrol.2025.134193",

language = "English",

volume = "663",

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T1 - Impact of inland boundary conditions on seawater intrusion modeling in stratified coastal aquifers under sea-level rise

AU - Liu, Yuzheng

AU - Li, Bojun

AU - Song, Wenjin

AU - He, Yu

AU - Guo, Quan

AU - Kim, Minjae

AU - Rathore, Saubhagya Singh

AU - Luo, Jian

PY - 2025/12

Y1 - 2025/12

N2 - This study systematically examines the impact of inland boundary conditions on seawater intrusion modeling in general stratified coastal aquifers under sea-level rise (SLR). We derived analytical solutions for seawater wedge toe positions in stratified aquifers with general head boundary (GHB) conditions and compiled solutions for constant head boundary (CHB), constant flux boundary (CFB), and GHB conditions in both homogeneous and stratified aquifers. Additionally, we introduced the concept of equivalent boundary conditions and developed equations to ensure consistent steady-state toe positions across different boundary types. Unlike previous studies focusing on specific layering configurations, we conducted a comprehensive sensitivity analysis of seawater intrusion in general stratified aquifers using transmissivity centroid elevation (TCE). Our results show that SLR generally exacerbates seawater intrusion, with unconfined aquifers exhibiting higher sensitivity across all boundary conditions. Among boundary types, CHB conditions were the most sensitive to SLR, CFB the least, and GHB showed an intermediate response depending on its distance from the model boundary. Furthermore, seawater intrusion increases with the TCE of the stratified aquifer under SLR, suggesting that high-permeability or preferential flow layers near the surface amplify the impact of SLR. These findings emphasize the importance of selecting appropriate boundary conditions when evaluating SLR-driven seawater intrusion in stratified coastal aquifers.

AB - This study systematically examines the impact of inland boundary conditions on seawater intrusion modeling in general stratified coastal aquifers under sea-level rise (SLR). We derived analytical solutions for seawater wedge toe positions in stratified aquifers with general head boundary (GHB) conditions and compiled solutions for constant head boundary (CHB), constant flux boundary (CFB), and GHB conditions in both homogeneous and stratified aquifers. Additionally, we introduced the concept of equivalent boundary conditions and developed equations to ensure consistent steady-state toe positions across different boundary types. Unlike previous studies focusing on specific layering configurations, we conducted a comprehensive sensitivity analysis of seawater intrusion in general stratified aquifers using transmissivity centroid elevation (TCE). Our results show that SLR generally exacerbates seawater intrusion, with unconfined aquifers exhibiting higher sensitivity across all boundary conditions. Among boundary types, CHB conditions were the most sensitive to SLR, CFB the least, and GHB showed an intermediate response depending on its distance from the model boundary. Furthermore, seawater intrusion increases with the TCE of the stratified aquifer under SLR, suggesting that high-permeability or preferential flow layers near the surface amplify the impact of SLR. These findings emphasize the importance of selecting appropriate boundary conditions when evaluating SLR-driven seawater intrusion in stratified coastal aquifers.

KW - Boundary condition

KW - General head boundary

KW - Sea-level rise

KW - Seawater intrusion

KW - Stratified aquifer

UR - https://www.scopus.com/pages/publications/105014946656

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DO - 10.1016/j.jhydrol.2025.134193

M3 - Article

AN - SCOPUS:105014946656

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JF - Journal of Hydrology

M1 - 134193

ER -

Impact of inland boundary conditions on seawater intrusion modeling in stratified coastal aquifers under sea-level rise

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