Identifying the effect of tides on groundwater level fluctuations on Gili Ketapang Island, Indonesia
Abstract
This research aims to identify the effect of tides on groundwater level fluctuation in Gili Ketapang Island by using a combination of field monitoring and hydrodynamic modeling. Groundwater data were collected from 5 July to 17 August 2018 from two wells monitoring, while the hydrodynamic model was adopted to identify sea-level conditions. The result explains the sea level around the island is similar among extremely strong correlations between the points. The hydrodynamic model proves a standing wave due to tidal amplification in Madura Strait waters. The effect of tides on the groundwater level characterized by decreasing in amplitudes and time lags as increasing the distance from the coast.
Keyword : tides, groundwater level fluctuations, Gili Ketapang Island, hydrodynamic model
How to Cite
Purnomo, A. D., Marfai, M. A., & Husrin, S. (2021). Identifying the effect of tides on groundwater level fluctuations on Gili Ketapang Island, Indonesia. Journal of Environmental Engineering and Landscape Management, 29(3), 215-228. https://doi.org/10.3846/jeelm.2021.14618
This work is licensed under a Creative Commons Attribution 4.0 International License.
References
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Danish Hydraulic Institute. (2017). MIKE 21 flow model FM: Hydrodynamic module. User guide. https://manuals.mikepoweredbydhi.help/2017/Coast_and_Sea/MIKE_FM_HD_2D.pdf
Dong, L., Shimada, J., Kagabu, M., & Yang, H. (2015). Barometric and tidal-induced aquifer water level fluctuation near the Ariake Sea. Environmental Monitoring and Assessment, 187(1), 4187–4203. https://doi.org/10.1007/s10661-014-4187-6
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Falkland, A. C. (1993). Hydrology and water management on small tropical islands. In J. S. Gladwell, Hydrology of Warm Humid Regions (pp. 263–303). IAHS Press.
Falkland, A. C., Custodio, E., Diaz Arenas, A., & Simler, L. (1991). Hydrology and water resources of small islands: A practical guide. UNESCO Publisher.
Fetter, Jr. C. W. (1972). Position of the saline water interface beneath oceanic islands. Water Resources Research, 8(5), 1307– 1315. https://doi.org/10.1029/WR008i005p01307
Geospatial Information Agency. (2019, 25 June). Raster of bathymetry: BATNAS_110E-115E_10S-05S_MSL_v1.1. http://tides.big.go.id/DEMNAS/
Geospatial Information Agency. (2019, 25 June). Shapefile of shoreline data of East Java. Indonesia-Geospatial Portal. https://portal.ina-sdi.or.id/downloadaoi/
Godin, G. (1993). On tidal resonance. Continental Shelf Research, 13(1), 89–107. https://doi.org/10.1016/0278-4343(93)90037-X
Hadi, S., & Radjawane, I.M. (2010). Arus Laut. Institut Teknologi Bandung.
Hegge, B. J., & Masselink, G. (1991). Groundwater-table responses to wave run-up: An experimental study from Western Australia. Journal of Coastal Research, 7(3), 623–634.
Heiss, J. W., & Michael, H. A. (2014). Saltwater-freshwater mixing dynamics in a sandy beach aquifer over tidal, spring-neap, and seasonal cycles. Water Resources Research, 50(8), 6747–6766. https://doi.org/10.1002/2014WR015574
Hidayati, N., Purnawali, H. S., & Kusumawati, D. W. (2016). Prediksi perubahan garis pantai Pulau Gili Ketapang, Probolinggo dengan menggunakan one-line model [Coference presentation]. Seminar Nasional Perikanan dan Kelautan VI, Fakultas Perikanan dan Ilmu Kelautan, Universitas Brawijaya, Malang.
Hill, D. F. (2016). Spatial and temporal variability in tidal range: Evidence, causes, and effects. Current Climate Change Reports, 2, 232–241. https://doi.org/10.1007/s40641-016-0044-8
Holleman, R. C., & Stacey, M. T. (2014). Coupling of sea level rise, tidal amplification, and inundation. Journal of Physical Oceanography, 44(5), 1439–1455. https://doi.org/10.1175/JPO-D-13-0214.1
Holt, J. T., Allen, J. I., Proctor, R., & Gilbert, F. (2005). Error quantification of a high-resolution coupled hydrodynamicecosystem coastal-ocean model: Part 1 model overview and assessment of the hydrodynamics. Journal of Marine Systems, 57(1–2), 167–188. https://doi.org/10.1016/j.jmarsys.2005.04.008
Horn, D. P. (2002). Beach groundwater dynamics. Geomorphology, 48(1–3), 121–146. https://doi.org/10.1016/S0169-555X(02)00178-2
Hsieh, P., Hsu, H., Liao, C. B., & Chiueh, P. (2015). Groundwater response to tidal fluctuation and rainfall in a coastal aquifer. Journal of Hydrology, 521, 132–140. https://doi.org/10.1016/j.jhydrol.2014.11.069
Huang, A., Rao, Y. R., & Lu, Y. (2010). Evaluation of a 3-D hydrodynamic model and atmospheric forecast forcing using observations in Lake Ontario. Journal of Geophysical Research, 115(2), C02004. https://doi.org/10.1029/2009JC005601
Huang, F., Chuang, M., Wang, G. S., & Yeh, H. (2015). Tideinduced groundwater level fluctuation in a U-shaped coastal aquifer. Journal of Hydrology, 530, 291–305. https://doi.org/10.1016/j.jhydrol.2015.09.032
Husrin, S. (2018). Kajian Daya Dukung Sumberdaya Airtanah di Pulau Kecil yang Berpenduduk Padat (Studi Kasus: Pulau Gili Ketapang, Probolinggo, Jawa Timur) [Conference presentation]. Kuliah Umum Analisis Kerentanan Pesisir dari Sisi Teknik Pantai. Fakultas Geografi Universitas Gadjah Mada.
Jasonsmith, J. F., Macdonald, B. C. T., & White, I. (2017). Earthtide-induced fluctuations in the salinity of an inland river, New South Wales, Australia: A short-term study. Environmental Monitoring and Assessment, 189, 188. https://doi.org/10.1007/s10661-017-5880-z
Jeng, D. S., Li, L., & Barry, D. A. (2002). Analytical solution for tidal propagation in a coupled semi-confined/phreatic coastal aquifer. Advances in Water Resources, 25(5), 577–584. https://doi.org/10.1016/S0309-1708(02)00016-7
Jeng, D. S., Mao, X., Enot, P., Barry, D. A., Li, L., & Binlet, A. (2005). Spring-neap tide-induced beach water table fluctuations and its influence on the behaviour of a coastal aquifer adjacent to a low-relief estuary (Research Report). Department of Civil Engineering, University of Sydney.
Kim, J., Lee, J., Cheong, T., Kim, R., Koh, D., Ryu, J., & Chang, H. (2005). Use of time series analysis for the identification of tidal effect on groundwater in the coastal area of Kimje, Korea. Journal of Hydrology, 300(1–4), 188–198. https://doi.org/10.1016/j.jhydrol.2004.06.004
Kim, K., Seong, H., Kim, T., Park, K., Woo, N., Park, Y., Koh, G., & Park, W. (2006). Tidal effects on variations of fresh – saltwater interface and groundwater flow in a multilayered coastal aquifer on a volcanic island (Jeju Island, Korea). Journal of Hydrology, 330(1–4), 525–542. https://doi.org/10.1016/j.jhydrol.2006.04.022
Kusmanto, E., Hasanudin, M., & Setyawan, W. B. (2016). Amplifikasi Pasang Surut dan Dampaknya terhadap Perairan Pesisir Probolinggo. Oseanologi dan Limnologi di Indonesia, 1(3), 69–80.
Levanon, E., Shalev, E., Yechieli, Y., & Gvirtzman, H. (2016). Fluctuations of fresh-saline water interface and of water table induced by sea tides in unconfined aquifers. Advances in Water Resources, 96, 34–42. https://doi.org/10.1016/j.advwatres.2016.06.013
Levanon, E., Yechielli, Y., Gvirtzman, H., & Shalev, E. (2017). Tide-induced fluctuations of salinity and groundwater level in unconfined aquifers – Field measurements and numerical model. Journal of Hydrology, 551, 665–675. https://doi.org/10.1016/j.jhydrol.2016.12.045
Liu, Y., Shang, S., & Mao, X. (2012). Tidal effects on groundwater dynamics in coastal aqui- fer under different beach slopes. Journal of Hydrodynamics, 24(1), 97–106. https://doi.org/10.1016/S1001-6058(11)60223-0
Mao, X., Enot, P., Barry, D. A., Li, L., Binley, A., & Jeng, D.-S. (2006). Tidal influence on behaviour of a coastal aquifer adjacent to a low-relief estuary. Journal of Hydrology, 327(1–2), 110–127. https://doi.org/10.1016/j.jhydrol.2005.11.030
Narulita, I., Santoso, H., Hantoro, W. S., & Djuwansah, M. R. (2005). Pengaruh pasang surut laut terhadap posisi kualitas air tanah di Pulau Pari, Kepulauan Seribu, DKI Jakarta. In P. E. Hehanussa, & H. Bakti, Sumberdaya Air di Pulau Kecil. Indonesian Institute of Sciences.
Nielsen, P. (1990). Tidal dynamics of the water table in beaches. Water Resources Research, 26(9), 2127–2134. https://doi.org/10.1029/WR026i009p02127
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