Interaction Model of Rainfall, Lake, and Ground Waters
Abstract
This research intends to build an interaction model between rainfall, lake water, and ground water. The location of research is in the Sentani Lake where is placed in the Jayapura Regency-Papua-Indonesia. Sentani Lake is a lake in the Sentani Watershed. Sentani Lake is located between Jayapura City and Jayapura Regency-Papua Province. The area of Sentani Lake is 9,630 ha with the depth is 75 m over the sea. In the northern of this lake are the Cyclops Mountains (Dafonsero) that separate the Sentani Lake and the Pacific Sea. The Sentani Lake functions as the track of transportation, food source, drinking water source, and tourism. Based on the bathymetry analysis result which is obtained from the River Region Institution of Papua, the Sentani Lake has the smallest elevation from 13.05 mdpl until 71.5 mdpl with a maximum storage capacity of 4.8 milliard m3. The methodology of this research consists of 1) To set and to simulate of Hydrology Model; 2) Analysis of water balance; 3) To set up the hydro-geology model; 4) To simulate the integration of rainfall-lake water- ground water. The interaction model between rainfall and lake waters is built based on the relation between the outlet discharge and the rainfall at 10 points and then is validated at the 5 points of observation data. This model produces the formulation as follows: inflow to the lake from rainfall = 0.067 x rainfall – 5. The interaction model between the lake water level and the ground water level is built based on the value of ground water-level fluctuation and the lake water level at the 10 points, and it is validated at the 6 points of observation data. This model produces the following formulation: fluctuation of ground water level = 0.1529 x fluctuation of lake water level. By combining the ground water and run-off in the Sentani Watershed, it is known as follows: inflow total of lake = base-flow + 0.067 x rainfall – 5.
Keywords: lake, rainfall, lake water, ground water.
Full Text:
PDFReferences
MUCHLIS A., BISRI M., LIMANTARA L. M., and SHOLICHIN M. Design Flood of the Mahakam Lake Cascade for Reducing the Flood Downstream. Journal of Southwest Jiaotong University, 2021, 56(4): 279-287. https://doi.org/10.35741/issn.0258-2724.56.4.23
SMITH B. D., & ZEDER M. A. The Onset of the Anthropocene. Anthropocene, 2013, 4: 8–13. https://doi.org/10.1016/j.ancene.2013.05.001
CHANG Y., HOU K., LI X., ZHANG Y., and CHEN P. Review of land use and land cover change research progress. IOP Conference Series: Earth and Environmental Science, 2018, 113: 012087. http://dx.doi.org/10.1088/1755-1315/113/1/012087
CHEN J., LIAO A., CHEN J., PENG S., CHEN L., and ZHANG H. 30-meter global land cover data product- Globe Land30. Geomatics World, 2017, 24(1): 1-8.
JUWONO P. T., LIMANTARA L. M., and AMRIE S. The effect of land use change to the depth and area of inundation in the Bang sub-watershed-Malang-Indonesia. International Journal of GEOMATE, 2019, 16(53): 238-244. http://dx.doi.org/10.21660/2019.53.96946
PRIYANTORO D., & LIMANTARA L. M. Conformity Evaluation of Synthetic Unit Hydrograph (Case Study at Upstream Brantas Sub-Watershed, East Java Province of Indonesia). Journal of Water and Land Development, 2017, 35: 173–183. https://doi.org/10.1515/jwld-2017-0082
YOHANNES A. W., COTTER M. C., KELBORO G., and DESSALEGN W. Land use and land cover changes and theor effects on the landscape of Abaya-Chamo Basin. Land, 2018, 7(1): 2. https://doi.org/10.3390/land7010002
HUA W., CHEN H., and SUN S. Assessing climatic impacts of future land use and land cover change projected with the CanESM2 model. International Journal of Climatology, 2015, 35(12): 3661-3675. https://doi.org/10.1002/joc.4240
LI G., ZHANG F., and JING Y. Response of evapotranspiration to changes in land use and land cover and climate in China during 2001-2013. Science of the Total Environment, 2017, 596-597: 256-265. https://doi.org/10.1016/j.scitotenv.2017.04.080
SANTOS M., & FRAGOSO M. Precipitation thresholds for triggering floods in the Corgo Basin, Portugal. Water, 2016, 8(9): 376. https://doi.org/10.3390/w8090376
QUANJIU W., TING Y., YANLI L., GUANGXU Z., and PENGYU Z. Review of Soil Nutrient Transport in Runoff and Its Controlling Measures. Transactions of the Chinese Society of Agricultural Machinery, 2016, 47(6): 67-82. http://nyjxxb.net/index.php/journal/article/view/85
MARKOVICH K. H., MANNING A. H., CONDON L. E., and MCINTOSH J. C. Mountain-Block Recharge: A Review of Current Understanding. Water Resources Research, 2019, 55: 8278-8304. https://doi.org/10.1029/2019WR025676
COUNCIL G. W. Simulating Lake-Groundwater Interaction with MODFLOW, 1997. https://smartech.gatech.edu/bitstream/handle/1853/44196/CouncilG-97.pdf
CHENG X., & ANDERSON M. P. Numerical simulation of ground-water interaction with lakes allowing for fluctuating lake levels. Groundwater, 1993, 31(6): 929-933. https://doi.org/10.1111/j.1745-6584.1993.tb00866.x
KELBE B. E., & GERMISHUYSE T. The interaction between coastal lakes and the surrounding aquifer. In: SILILO O. (ed.) Proceedings of the XXX Congress on Groundwater: Past Achievements and Future Challenges. Balkema, Cape Town, Rotterdam, 2000: 395-400. https://www.researchgate.net/publication/291629912_The_Interaction_between_Coastal_Lakes_and_the_surrounding_Aquifer
Refbacks
- There are currently no refbacks.
