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Volume 8 Issue 1
Mar.  2020
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Article Contents
Muhammad Juandi. 2020: Water sustainability model for estimation of groundwater availability in Kemuning district, Riau-Indonesia. Journal of Groundwater Science and Engineering, 8(1): 20-29. doi: 10.19637/j.cnki.2305-7068.2020.01.003
Citation: Muhammad Juandi. 2020: Water sustainability model for estimation of groundwater availability in Kemuning district, Riau-Indonesia. Journal of Groundwater Science and Engineering, 8(1): 20-29. doi: 10.19637/j.cnki.2305-7068.2020.01.003

Water sustainability model for estimation of groundwater availability in Kemuning district, Riau-Indonesia

doi: 10.19637/j.cnki.2305-7068.2020.01.003
Funds:

Muhammad Juandi

  • Publish Date: 2020-03-28
  • There are rising interests in the utility of groundwater in various aspects, which is capable of triggering problematic issues. The excessive exploitation for anthropologic uses, without regards to aquifer capacity, will decreases the water table as well as capacity of groundwater in the aquifer. This research is aimed to provide aquifer model of underground water by consideration of various environmental factors, with the propensity of being modeled, in an attempt to predict groundwater conditions in subsequent years. The purpose of this research is to forecast water requirements, availability, as well as three-dimensional model of groundwater depth in Kemuning, Indragiri Hilir Regency-Indonesia between 2015 and 2022. Furthermore, various environmental factors, from aquifer profiles to anthropologic demand, are taken into account in the evaluated model, including water requirements, encompassing recharge and aquifer parameters, which consists of storativity and transmissivity. From anthropologic side are domestic requirements, trade, public facilities, agriculture, and livestock. The results show that groundwater availability in Kemuning is to be safe condition, and average difference is 1.06×108 m3/yr. The coefficient of storativity and transmissivity are 16.514 m2/day and 9 897.26 m2/day, respectively, while the average depth was recorded as 2.8965 m to 10.4927 m.
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  • ZHANG Ji-en, WANG Tian-ming, GE Jian-ping. 2015. Assessing vegetation cover dynamics induced by policy-driven ecological restoration and implication to soil erosion in southern China. PLOS One, 10(6): e0131352.
    LIU Chang-ming, YU Jing-jie, Kendy E. 2001. Groundwater exploitation and its impact on the environment in the North China Plain. Water Tnternational, 26(2): 265-272.
    Caplan J S, Galanti R C, Olshevski S, et al. 2019. Water relations of street trees in green infrastructure tree trench systems. Urban for Urban Greening, 41: 170-178.
    LU Chen-xi, ZHAO Ting-yang, SHI Xiao-liang, et al. 2018. Ecological restoration by afforestation may increase groundwater depth and create potentially large ecological and water opportunity costs in arid and semiarid China. Journal of Cleaner Production, 176: 1213-1222.
    ZHANG Xuan-chang, MI Feng, LU Nan, et al. 2017. Green space water use and its impact on water resources in the capital region of China. Physics and Chemistry of the Earth, Parts A/B/C, 101: 185-194.
    Ball P. 2017. Water is an active matrix of life for cell and molecular biology. Proc Natl Acad Sci USA, 114(51):13327-13335.
    Kobielska P A, Howarth A J, Farha O K, et al. 2018. Metal-organic frameworks for heavy metal removal from water. Coordination Chemistry Reviews, 358, 92-107.
    Muhammad Juandi, Antonius Surbakti, Riad Syech, et al. 2017. Potential of aquifers for groundwater exploitation using Cooper-Jacob equation. Journal of Environmental Science and Technology, 10: 215-219.
    Bratina J N. 2014. Perception, experience and the use of public urban spaces by residents of urban neighbourhoods. Urbani Izziv, 25: 107-125.
    Dasgupta N, Ranjan S, Ramalingam C. 2018. Applications of nanotechnology in agriculture and water quality management. Environmental Chemistry Letters, 15(4): 591-605.
    Treija S, Bratu?kins U, Bondars E. 2012. Green open space in large scale housing estates: A place for challenge. Journal of Architecture Urbanism, 3: 264-271.
    Wada Y, Wisser D, Bierkens M F P. 2014. Global modeling of withdrawal, allocation and consumptive use of surface water and groundwater resources. Earth Sys Dyn, 5: 15-40.
    Gavin K and Xue J. 2008. A simple method to analyze infiltration into unsaturated soil slopes. Comput. Geotech, 35: 223-230.
    Rossatto D R , de Carvalho Ramos Silva L, Villalobos-Vega R , et al. 2012. Depth of water uptake in woody plants relates to groundwater level and vegetation structure along a topographic gradient in a neotropical savanna. Environmental & Exprimental Botany, 77: 259-266.
    Brack W, Dulio V, ?gerstrand M, et al. 2017. Towards the review of the European Union water framework management of chemical contamination in European surface water resources. Science of the Total Environment, 576: 720-737.
    Dykes A P, Thornes J B. 2000. Hillslope hydrology in tropical rainforest steeplands in Brunei. Hydrological Processes, 14: 215-235.
    Mahmoudi P, Hatton Macdonald D, Crossman N D, et al. 2015. Space matters: The importance of amenity in planning metropolitan growth. Aust J Agric Resour Econ, 57: 38-59.
    Kumalajati E, Sabarnudi S, Budiadi, et al. 2015. Analysis of water demand and availability in Keduang watershed in Central Java. J Teknosains, 5: 9-19.
    National Standardization Agency (BSN). 2002. Preparation of Resource Balance, Section 1: Spatial Water Resources-SNI 19-6728-2002; National Standardization Agency: Jakarta, Indonesia.
    Rezaei Kalvani S, Sharaai A, Manaf L, et al. 2019. Assessing ground and surface water scarcity indices using ground and surface water footprints in the Tehran Province of Iran. Appl Ecol Environ Res, 17: 4985-4997.
    Samso R, Garcia J, Molle P, et al. 2016. Modelling bioclogging in variably saturated porous media and the interactions between surface/subsurface flows: Application to Constructed Wetlands. Journal of Environmental Management, 165: 271-279.
    Fetter C W. 1994. Applied Hydrogeology. Prentice Hall: New Jersey, USA.
    Juandi M and Syahril S. 2017. Empirical relationship between soil permeability and resistivity, and its application for determining the groundwater gross recharge in Marpoyan Damai, Pekanbaru, Indonesia. Water Practice and Technology, 12(3): 660-666.
    Thomas R and Duraisamy V. 2018. Hydrogeological delineation of groundwater vulnerability to droughts in semi-arid areas of western Ahmednagar district. The Egyptian Journal of Remote Sensing and Space Science, 21: 121-137.
    Davis A Y, Jung J, Pijanowski B C, et al. 2016. Combined vegetation volume and “greenness” affect urban air temperature. Applied Geography, 71, 106-114.
    Beven K, Germann P. 2010. Macropores and water flow in soils revisited. Water Resources Research, 49(6): 3071-3092.
    Chonova T, Lecomte V, Bertrand Krajewski J L, et al. 2018. The SIPIBEL project: Treatment of hospital and urban wastewater in a conventional urban wastewater treatment plant. Environmental Science and Pollution Research, 25: 9197-9206.
    Canteiro M, Olea S, Escolero O, et al. 2019. Relationships between urban aquifers and preserved areas south of Mexico City. Groundwater Sustainable Dev, 8: 373-380.
    Crosbie R S, Peeters L J M, Herron N, et al. 2018. Estimating groundwater recharge and its associated uncertainty: Use of regression kriging and the chloride mass balance method. Journal of Hydrology, 561: 1063-1080.
    Todd D K and Larry W M. 2005. Groundwater Hydrology, 3rd ed, John Wiley & Sons, Inc, New Jersey, USA.
    Indonesian Statistics (BPS). 2018. Kemuning District in numbers. BPS Indragiri Hilir regency: Tembilahan, Indonesia.
    Guymon G. 1994. Unsaturated Zone Hydrogeology. Prentice Hall: New Jersey, USA.
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