A numerical simulation study for controlling seawater intrusion by using hydraulic and physical barriers

LYU Panpan; SONG Jian; WU Jianfeng; WU Jichun

doi:10.16030/j.cnki.issn.1000-3665.202007068

2021 Vol. 48, No. 4

Article Contents

Article navigation > Hydrogeology & Engineering Geology > 2021 > 48(4): 32-40

Next Article Previous Article

LYU Panpan, SONG Jian, WU Jianfeng, WU Jichun. A numerical simulation study for controlling seawater intrusion by using hydraulic and physical barriers[J]. Hydrogeology & Engineering Geology, 2021, 48(4): 32-40. doi: 10.16030/j.cnki.issn.1000-3665.202007068

Citation:

LYU Panpan, SONG Jian, WU Jianfeng, WU Jichun. A numerical simulation study for controlling seawater intrusion by using hydraulic and physical barriers[J]. Hydrogeology & Engineering Geology, 2021, 48(4): 32-40. doi: 10.16030/j.cnki.issn.1000-3665.202007068

A numerical simulation study for controlling seawater intrusion by using hydraulic and physical barriers

Key Laboratory of Surficial Geochemistry, Ministry of Education，School of Earth Sciences and Engineering, Nanjing University, Nanjing, Jiangsu　210023, China

More Information

Corresponding author: WU Jianfeng, jfwu@nju.edu.cn

Received Date: 28 July 2020

Revised Date: 17 October 2020

Publish Date: 15 July 2021

Abstract

Abstract

Seawater intrusion (SI) has become a global concern for groundwater environment. SI not only seriously threatens freshwater resources in coastal aquifers, but also undermines the balance of coastal ecosystem and further restricts the socioeconomic development. This paper simulates the SI process in a 2D synthetic aquifer constructed from sandbox experiment using the simulator SEAWAT-2000. The transport phenomenon of the brackish water interface is investigated by altering the location and injection rate of a recharge well and the layout of the physical barrier. The results show that when the recharge well is located near the toe of the salt water wedge of 40 cm from the coastline and 5 cm from the surface, the optimal performance of the recharge scheme is achieved with the repulsion rate up to 21.5%. When the physical barrier is located 10 cm from the coastline and the penetration depth is 35 cm, the toe of saltwater wedge is effectively driven to the coastline with the repulsion rate up to 81.8%. Moreover, we simulate the variable-density groundwater flow and transport in a typical two-dimensional section of coastal aquifer in the Longkou District of Shandong Province. The SI model is established to evaluate the influences of different management schemes (i.e., physical barrier and recharge well) on the prevention of seawater intrusion. The results show that when the physical barrier is located 600 m from the coastline and the penetration depth is 18 m, the toe of salt water wedge is effectively driven back to the coastline with the repulsion rate up to 28.4%. The results reveal the influence of hydraulic and physical barriers under different settings on the migration rule of the brackish water interface. The findings may provide insights into the optimization suggestions for coastal groundwater management under site conditions.
- seawater intrusion /
- numerical simulation /
- SEAWAT-2000 /
- flow barrier /
- physical barrier /
- recharge well

FullText(HTML)

References

[1]	WERNER A D. On the classification of seawater intrusion[J]. Journal of Hydrology,2017,551:619 − 631. doi: 10.1016/j.jhydrol.2016.12.012 CrossRef Google Scholar
[2]	李雪, 叶思源. 海水入侵调查方法研究进展[J]. 海洋地质与第四纪地质,2016,36(6):211 − 217. [LI Xue, YE Siyuan. Progress in seawater intrusion[J]. Marine Geology & Quaternary Geology,2016,36(6):211 − 217. (in Chinese with English abstract) Google Scholar
[3]	WERNER A D, BAKKER M, POST V E A, et al. Seawater intrusion processes, investigation and management: Recent advances and future challenges[J]. Advances in Water Resources,2013,51:3 − 26. doi: 10.1016/j.advwatres.2012.03.004 CrossRef Google Scholar
[4]	KETABCHI H, MAHMOODZADEH D, ATAIEASHTIANI B, et al. Sea-level rise impacts on seawater intrusion in coastal aquifers: Review and integration[J]. Journal of Hydrology,2016,535:235 − 255. doi: 10.1016/j.jhydrol.2016.01.083 CrossRef Google Scholar
[5]	SHERIF M M, SINGH V P. Effect of climate change on sea water intrusion in coastal aquifers[J]. Hydrological Processes,1999,13(8):1277 − 1287. doi: 10.1002/(SICI)1099-1085(19990615)13:8<1277::AID-HYP765>3.0.CO;2-W CrossRef Google Scholar
[6]	NAEEM M F A A, YUSOFF I, NG T F, et al. A study on the impact of anthropogenic and geogenic factors on groundwater salinization and seawater intrusion in Gaza coastal aquifer, Palestine: An integrated multi-techniques approach[J]. Journal of African Earth Sciences,2019,156:75 − 93. doi: 10.1016/j.jafrearsci.2019.05.006 CrossRef Google Scholar
[7]	王玉广, 王传珺, 刘志华, 等. 地下水位和海平面变化对绥中砂质海岸海水入侵影响[J]. 海洋环境科学,2019,38(3):347 − 352. [WANG Yuguang, WANG Chuanjun, LIU Zhihua, et al. Impact to the the seawater intrusion around sand Coast in Suizhong with the variations of groundwater level and sea level[J]. Marine Environmental Science,2019,38(3):347 − 352. (in Chinese with English abstract) doi: 10.12111/j.mes20190305 CrossRef Google Scholar
[8]	BADARUDDIN S, WERNER A D, MORGAN L K. Water table salinization due to seawater intrusion[J]. Water Resources Research,2015,51(10):8397 − 8408. doi: 10.1002/2015WR017098 CrossRef Google Scholar
[9]	WERNER A D, SIMMONS C T. Impact of sea-level rise on sea water intrusion in coastal aquifers[J]. Groundwater,2009,47(2):197 − 204. doi: 10.1111/j.1745-6584.2008.00535.x CrossRef Google Scholar
[10]	崔相飞, 周训, 徐中平, 等. 海岸带咸淡水界面的研究进展[J]. 水文地质工程地质,2018,45(2):29 − 35. [CUI Xiangfei, ZHOU Xun, XU Zhongping, et al. Advances in research on the fresh water-salt water interface in coastal zones[J]. Hydrogeology & Engineering Geology,2018,45(2):29 − 35. (in Chinese with English abstract) Google Scholar
[11]	ZHOU X, SONG C, LI T. Estimation of the inland extending length of the freshwater-saltwater interface in coastal unconfined aquifers[J]. Hydrological Sciences Journal,2016,61(13):2367 − 2375. doi: 10.1080/02626667.2015.1111516 CrossRef Google Scholar
[12]	赵洁, 林锦, 吴剑锋, 等. 大连周水子海水入侵区地下水多目标优化管理模型[J]. 水文地质工程地质,2017,44(5):25 − 32. [ZHAO Jie, LIN Jin, WU Jianfeng, et al. A multi-objective simulation-optimization model for optimal control of seawater intrusion in the Zhoushuizi district of Dalian[J]. Hydrogeology & Engineering Geology,2017,44(5):25 − 32. (in Chinese with English abstract) Google Scholar
[13]	JAVADI A, HUSSAIN M, SHERIF M, et al. Multi-objective optimization of different management scenarios to control seawater intrusion in coastal aquifers[J]. Water Resources Management,2015,29(6):1843 − 1857. doi: 10.1007/s11269-015-0914-1 CrossRef Google Scholar
[14]	梁越, 陈建生, 陈亮. 注水井水力帷幕防治海水入侵的机理与应用[J]. 长江科学院院报,2009,26(10):133 − 136. [LIANG Yue, CHEN Jiansheng, CHEN Liang. Mechanism and application of water injecting hydraulic curtain stopping seawater intrusion[J]. Journal of Yangtze River Scientific Research Institute,2009,26(10):133 − 136. (in Chinese with English abstract) doi: 10.3969/j.issn.1001-5485.2009.10.031 CrossRef Google Scholar
[15]	ARMANUOS A M, AL-ANSARI N, YASEEN Z M. Assessing the effectiveness of using recharge Wells for controlling the saltwater intrusion in unconfined coastal aquifers with sloping beds: numerical study[J]. Sustainability,2020,12(7):2685. doi: 10.3390/su12072685 CrossRef Google Scholar
[16]	武雅洁, 冯峰, 雷鑫. 地下截渗墙影响下的咸水入侵规律研究[J]. 中国海洋大学学报(自然科学版),2018,48(8):131 − 138. [WU Yajie, FENG Feng, LEI Xin. Study on the behavior of saltwater intrusion under the installation of subsurface cutoff wall[J]. Periodical of Ocean University of China,2018,48(8):131 − 138. (in Chinese with English abstract) Google Scholar
[17]	EBELING P, HÄNDEL F, WALTHER M. Potential of mixed hydraulic barriers to remediate seawater intrusion[J]. Science of the Total Environment,2019,693:133478. doi: 10.1016/j.scitotenv.2019.07.284 CrossRef Google Scholar
[18]	KALERIS V K, ZIOGAS A I. The effect of cutoff walls on saltwater intrusion and groundwater extraction in coastal aquifers[J]. Journal of Hydrology,2013,476:370 − 383. doi: 10.1016/j.jhydrol.2012.11.007 CrossRef Google Scholar
[19]	ABDOULHALIK A, AHMED A, HAMILL G A. A new physical barrier system for seawater intrusion control[J]. Journal of Hydrology,2017,549:416 − 427. doi: 10.1016/j.jhydrol.2017.04.005 CrossRef Google Scholar
[20]	ALLOW K A. The use of injection wells and a subsurface barrier in the prevention of seawater intrusion: a modelling approach[J]. Arabian Journal of Geosciences,2012,5(5):1151 − 1161. doi: 10.1007/s12517-011-0304-9 CrossRef Google Scholar
[21]	JANARDHANA M R, KHAIRY H. Simulation of seawater intrusion in coastal aquifers: a case study on the Amol–Ghaemshahr coastal aquifer system, Northern Iran[J]. Environmental Earth Sciences,2019,78(24):1 − 19. Google Scholar
[22]	CHANG Y W, HU B X, XU Z X, et al. Numerical simulation of seawater intrusion to coastal aquifers and brine water/freshwater interaction in south coast of Laizhou Bay, China[J]. Journal of Contaminant Hydrology,2018,215:1 − 10. doi: 10.1016/j.jconhyd.2018.06.002 CrossRef Google Scholar
[23]	陈开荣, 陈汉宝, 赵海亮. 基于SEAWAT的海水入侵数值模拟[J]. 水资源与水工程学报,2012,23(6):140 − 145. [CHEN Kairong, CHEN Hanbao, ZHAO Hailiang. Three-dimensional numerical simulation of seawater intrusion based on SEAWAT[J]. Journal of Water Resources and Water Engineering,2012,23(6):140 − 145. (in Chinese with English abstract) Google Scholar
[24]	LANGEVIN C D, THORNE JR D T, DAUSMAN A M, et al. SEAWAT version 4: a computer program for simulation of multi-species solute and heat transport[R]. Reston: United state Geological Survey, 2008. Google Scholar
[25]	SIMPSON M J. SEAWAT-2000: variable-density flow processes and integrated MT3DMS transport processes[J]. Ground Water,2004,42(5):642 − 646. doi: 10.1111/j.1745-6584.2004.tb02717.x CrossRef Google Scholar
[26]	LUYUN R, MOMII K, NAKAGAWA K. Effects of recharge wells and flow barriers on seawater intrusion[J]. Groundwater,2011,49(2):239 − 249. doi: 10.1111/j.1745-6584.2010.00719.x CrossRef Google Scholar