A Framework for Indicator-Based Water Sustainability Assessment

Document Type : Conceptual Paper

Authors

Water Research Institute

Abstract

Article Type: Conceptual
In order to preserve aquifers, their sustainability assessment against current and future stresses is of vital importance. For this purpose, groundwater sustainability indicators are introduced as measurable variables to provide groundwater system information in a comprehensive way. The indicators can be also served as useful tools to assess sustainability of these natural resources. It should be noted that these indicators are applied to identify sustainability over time (exploitation period) and are not designated to resolve the problem. Every sustainability indicator describes a specific aspect of groundwater systems. These indicators assess groundwater resources sustainability, based on the measurable data to provide information on the quantity and quality of the resources (status and current trends), as well as focusing on social (groundwater accessibility, exploitation and utilisation), environmental (vulnerability and pollution), political, economic, and managerial aspects of the resources. The main objective of this paper is to set up a framework to evaluate the sustainability of groundwater resources, in order to ensure the implementation of sustainable groundwater management across the country and to inform the decision and policymakers on the state of sustainability for a specified groundwater resource. In this regard, 21 indicators are presented in the framework of DPSIR in six categories of quantity and quality, environmental, social, economic, and political aspects of groundwater. With the purpose of integrating the indicators to reach the final number of sustainability, the categorical scaling method has been used with a minimum score of zero (least stable) and a maximum score of 100 (maximum sustainability), and each indicator is divided into five categories.

Keywords


Anbazhagan S. and Jothibasu A. 2016. Groundwater sustainability indicators in parts of Tiruppur and Coimbatore districts, Tamil Nadu. Journal of the Geological Society of India, 87(2): 161-168.
Antonakos A.K. and Lambrakis N.J. 2007. Development and testing of three hybrid methods for the assessment of aquifer vulnerability to nitrates, based on the drastic model, an example from NE Korinthia, Greece. Journal of Hydrology, 333(2): 288-304.
Bui N.T., Kawamura A., Amaguchi H., Du BUI D., and Truong N.T. 2016. Environmental Sustainability Assessment of Groundwater Resources in Hanoi, Vietnam by a simple AHP Approach. Journal of Japan Society of Civil Engineers, Ser. G (Environmental Research), 72(5): 137- 146.
Bui N.T., Kawamura A., Amaguchi H., Du Bui D., Truong N.T. and Nam H. 2017. Economic Sustainability Assessment of Groundwater Resources: Case Study of Hanoi, Vietnam. Journal of Environmental Science and Engineering, 6: 624-633.
Bui N.T., Kawamura A., Amaguchi H., Du Bui D., Truong N.T. and Nakagawa K. 2018. Social sustainability assessment of groundwater resources: A case study of Hanoi, Vietnam. Ecological indicators, 93: 1034-1042.
Campos-Gaytan J.R., Kretzschmar T. and Herrera-Oliva C.S. 2014. Future groundwater extraction scenarios for an aquifer in a semiarid environment: case study of Guadalupe Valley Aquifer, Baja California, Northwest Mexico. Environmental monitoring and assessment, 186(11): 7961-7985.
Du S., Su X. and Zhang W. 2013. Effective storage rates analysis of groundwater reservoir with surplus local and transferred water used in Shijiazhuang City, China. Water and Environment Journal, 27(2): 157-169.
Evans B.M. and Myers W.L. 1990. A GIS-based approach to evaluating regional groundwater pollution potential with DRASTIC. Journal of Soil and Water Conservation, 45(2): 242-245.
European Commission. 2006. On the Protection of Groundwater against Pollution and Deterioration; European Commission: Kirchberg, Luxembourg.
Gordon Groundwater Consultancy (Gordon Report). 2011. Sustainable Groundwater Management: Preliminary Approach for Assessing the Sustainability of Groundwater, submitted to CCME Water Management Development Committee, 48 p.
Hirata R., Suhogusoff A. and Fernandes A. 2007. Groundwater resources in the State of São Paulo (Brazil): The application of indicators. Anais da Academia Brasileira de Ciências, 79(1): 141-152.
Hosseini SM., Parizi E., Ataie-Ashtiani B. and Simmons T. 2019. Assessment of sustainable groundwater resources management using integrated environmental index: Case studies across Iran. Science of the Total Environment, 676: 792–810.
Hunsaker C.T., and Levine D.A. 1995. Hierarchical approaches to the study of water quality in rivers. BioScience, 45(3): 193-203.
Kardan moghaddam H. and Banihabib M.E. 2017. Investidation of interference of salt water in desert aquifer (Case study: South khorasan, sarayan aquifer). Journal of water and soil. 31(3): 673- 688.
Kristensen P. 2003. EEA core set of indicators. European Environment Agency.
Jafari F., Javadi S. and Karimi N. 2015. Forecasting of subsidence due to groundwater over exploitation using MODFLOW and interferometry technique in Radar imagery. 36th IAHR World Congress, Netherlands.
Juwana I., Muttil N. and Perera B.J.C. 2012. Indicator-based water sustainability assessment, A review. Science of the Total Environment, 438: 357-371.
Mattas C., Voudouris K., and Panagopoulos A. 2014. Integrated Groundwater Resources Management Using the DPSIR Approach in a GIS Environment Context: A Case Study from the Gallikos River Basin, North Greece. Water, 6(4): 1043-1068.
Pandey V.P., Shrestha S., Chapagain S.K. and Kazama F. 2011. A framework for measuring groundwater sustainability. Environmental Science & Policy, 14(4):396-407.
Policy Research Initiative. 2007. Canadian Water Sustainability Index (CWSI) project report. Government of Canada.
Pophare A.M., Lamsoge B.R., Katpatal Y.B. and Nawale V.P. 2014. Impact of over-exploitation on groundwater quality: a case study from WR-2 Watershed, India. Journal of earth system science, 123(7): 1541-1566.
Saaty T. L. 1980. The Analytical Hierarchy Process, Planning, Priority. Resource Allocation. RWS Publications, USA.
Remesan R. and Panda R.K. 2008. Groundwater vulnerability assessment, risk mapping, and nitrate evaluation in a small agricultural watershed: using the DRASTIC model and GIS. Environmental Quality Management, 17(4): 53-75.
Senent-Aparicio J., Perez-Sanchez J., Garcia-Arostegui J., Bielsa-Artero A. and Domingo-Pinillos J. 2015. Evaluating groundwater management sustainability under limited data availability in semiarid zones. Water, 7(8): 4305-4322.
Shannon C.E. 1948. A mathematical theory of communication. Bulletin System Technol journal, 27: 379-423.
Lipponen A. ed. 2007. Groundwater resources sustainability indicators. Paris: UNESCO.
Vrba J. and Zaporozec A. 1994. Guidebook on mapping groundwater vulnerability. Heise.
Wang Z. and Wu Q.I.A.N.G. 2006. Development of groundwater sustainability indicators. IAHS Publication, 302, p.29.
Werner A.D., Bakker M., Post V.E., Vandenbohede A., Lu C., Ataie-Ashtiani B., Simmons C.T. and Barry D.A. 2013. Seawater intrusion processes, investigation and management: recent advances and future challenges. Advances in Water Resources, 51: 3-26.
Zhang W., Gao L., Jiao X., Yu J., Su X. and Du S. 2014. Occurrence assessment of earth fissure based on genetic algorithms and artificial neural networks in Su-Xi-Chang land subsidence area, China. Geosciences Journal, 18(4): 485-493.
Zhai Y., Wang J., Huan H., Zhou J. and Wei W. 2013. Characterizing the groundwater renewability and evolution of the strongly exploited aquifers of the North China Plain by major ions and environmental tracers. Journal of Radioanalytical and Nuclear Chemistry, 296(3): 1263-1274.
CAPTCHA Image