TPA Piyungan menampung sampah hingga 550 ton/hari, sehingga air lindi (leachate) yang dihasilkan akan lebih besar dan dapat berdampak pada airtanah. Tujuan dari penelitian ini adalah untuk mengidentifikasi pencemaran air lindi pada airtanah di sekitar TPA Piyungan, dan dilakukan dengan menggunakan metode Electrical Resistivity Tomography (ERT) konfigurasi Wenner Beta, flownet, dan uji sifat fisik-kimia air. Hasil dari penelitian adalah (1) aliran airtanah secara dominan bergerak ke arah Barat Laut dari TPA Piyungan yang merupakan kawasan padat permukiman; (2) hasil geolistrik metode ERT di Dusun Pleret menunjukkan adanya distribusi air lindi pada kedalaman 5-20 m dengan nilai resistivitas 1-3 Ώmeter, sementara kedalaman airtanahnya juga berada pada kedalaman 5-15 meter; (3) hasil pengukuran DHL, TDS, dan salinitas yang menunjukkan sebagian sumur memiliki nilai di atas baku mutu yang dipersyaratkan untuk air minum. Oleh karena itu, airtanah sekitar TPA Piyungan terutama bagian Barat Laut telah tercemar akibat air lindi.

Abdullahi, N.K., Osazuwa, I.B., & Onugba, A. (2010). Detecting Municipal Solid Waste Leachate Plumes through Electrical Resistivity Survey and Physic-Chemical Analysis of Groundwater Samples. Journal of American Science, 6, 540–548.

Adji, T.N., & Sejati, S.P. (2014). Identification of Landform Analysis and Classification With GIS and Remote Sensing - A Micro Level Study. International Journal of Earth Sciences and Engineering, 4, 330-333.

Bernstone, C., Dahlin, T., Ohlsson, T., & Hogland, H. (2000). DC-Resistivity Mapping of Internal Landfill Structures: Two Pre-Excavation Surveys. Journal of Environmental Geology, 39(3-4), 360–371.

Bichet, V., Grisey, E., & Aleya, L. (2016). Spatial Characterization of Leachate Plume Using Electrical Resistivity Tomography in a Landfill Composed of Old and New Cells (Belfort, France). Journal of Engineering Geology, 211, 61–73.

Casado, I., Mahjoub, H., Lovera, R., Fernandez, R., & Casas, A.L. (2015). Use of Electrical Tomography Methods to Determinate the Extension and Main Migration Routes of Uncontrolled Landfill Leachates in Fractured Areas. Science of the Total Environment Journal, 506-507, 546–553.

Chambers, J.E., Kuras, O., Meldrum, P.I., Ogilvy, R.D., & Hollands, J. (2006). Electrical Resistivity Tomography Applied to Geologic, Hydrogeologic, and Engineering Investigations at a Former Waste-Disposal Site. Journal of Geophysic, 71(6), B231–B239.

Claret, F., Tournassat, C., Crouzet, C., Gaucher, E. C., Schäfer, T., Braibant, G., & Guyonnet, D. (2011). Metal Speciation in Landfill Leachates with a Focus on the Influence of Organic Matter. Journal of Waste Management, 31(9-10), 2036–2045.

Clement, R., Descloitres, M., Günther, T., Oxarango, L., Morra, C., Laurent, J.-P., & Gourc, J.-P. (2010). Improvement of Electrical Resistivity Tomography for Leachate Injection Monitoring. Journal of Waste Management, 30(3), 452–464.

Degueurce, A., Clement, R., Moreau, S., & Peu, P. (2016). On The Value of Electrical Resistivity Tomography for Monitoring Leachate Injection in Solid State Anaerobic Digestion Plants at Farm Scale. Journal of Waste Management, 56, 125-136.

Departemen Kesehatan RI. (2010). Peraturan Menteri Kesehatan Republik Indonesia No. 492/MENKES/PER/IV/2010 Tentang Persyaratan Kualitas Air Minum. Jakarta: Departemen Kesehatan RI.

Effendi, H. (2003). Telaah Kualitas Air. Yogyakarta: Penerbit Kanisius.

Grisey, E., & Aleya, L. (2016). Assessing the Impact of Leachate Plumes on Groundwater Quality in the Etueffont Landfill (Belfort, France). Journal of Environment Earth Science, 75, 913.

Kjeldsen, P., Barlaz, M.A., Rooker, A.P., Baun, A., Ledin, A., & Christensen, T.H. (2002). Present and Long-Term Composition of MSW Landfill Leachate: A Review. Crit. Rev. Journal of Environmental Science Technology, 32, 297–336.

Kurakalva, R. M., Aradhi, K. K., Mallela, K. Y., & Venkatayogi, S. (2016). Assessment of Groundwater Quality in and around the Jawaharnagar Municipal Solid Waste Dumping Site at Greater Hyderabad, Southern India. Procedia Environmental Sciences Journal, 35, 328–336.

Loke, M.H. (2000). Electrical Imaging Surveys for Environmental and Engineering Studies, A Practical Guide to 2-D and 3-D Surveys. http://www.geo.mtu.edu/~ctyoung/LOKENOTE.PDF diakses oleh Fajri Ramadhan pada 10 Juli 2018.

Maurya, P. K., Rønde, V. K., Fiandaca, G., Balbarini, N., Auken, E., Bjerg, P. L., & Christiansen, A. V. (2017). Detailed Landfill Leachate Plume Mapping Using 2D and 3D Electrical Resistivity Tomography - with Correlation to Ionic Strength Measured in Screens. Journal of Applied Geophysics, 138, 1–8.

Mor, S., Ravindra, K., Dahiya, R. P., & Chandra, A. (2006). Leachate Characterization and Assessment of Groundwater Pollution near Municipal Solid Waste Landfill Site. Environmental Monitoring and Assessment Journal, 118 (1-3), 435–456.

Morsy, K. M., Morsy, A. M., & Hassan, A. E. (2018). Groundwater Sustainability: Opportunity Out of Threat. Groundwater for Sustainable Development Journal, 7, 277–285.

Ofomola, M. O. (2018). Geophysical Assessment for Contaminant Hydrology in Ujevwu, Nigeria. Journal of African Earth Sciences, 138, 177–191.

Santosa, L.W. (2004). Studi Akuifer pada Bentanglahan Kepesisiran Kabupaten Kulonprogo Daerah Istimewa Yogyakarta. Jurnal Majalah Geografi Indonesia, 18(2), 117-133.

Slamet, J.S. (2000). Kesehatan Lingkungan. Yogyakarta: Gadjah Mada University Press.

Tebbut, T.H.Y. (1992). Principles of Water Quality Control. Oxford: Pergamon Press.

Todd, D.K & Mays, L.W. (2005). Groundwater Hydrology 3^rd Edition. New York: John Wiley and Sons.

Vaudelet, P., Schmutz, M., Pessel, M., Franceschi, M., Guérin, R., Atteia, O., & Bégassat, P. (2011). Mapping of Contaminant Plumes with Geoelectrical Methods. A Case Study in Urban Context. Journal of Applied Geophysics, 75(4), 738–751.

Widyastuti, M., Notosiswoyo, S., & Anggayana, K. (2006). Pengembangan Metode ‘DRASTIC’ untuk Prediksi Kerentanan Airtanah Bebas Terhadap Pencemaran di Sleman. Jurnal Majalah Geografi Indonesia, 20 (1), 32-51.