Telah dilakukan penelitian air-tanah di Kawasan Nuklir Pasar Jumat (KNPJ) menggunakan metode hidrokimia dan isotop alam. Penelitian dilakukan dengan mengambil sejumlah sampel air di beberapa kawasan KNPJ dan sekitarnya. Sampel air tersebut kemudian dianalisis konsentrasi kimia airnya (anion-kation) dan konsentrasi isotop alam d²H dan d¹⁸O menggunakan alat lasser counter. Analisis kimia air dilakukan menggunakan metode ion kromatografi dan titrasi. Tujuan penelitian ini, yaitu untuk mengetahui karakteristik air-tanah terhadap kemungkinan interaksi dengan air permukaan sekitarnya. Berdasarkan hasil analisis hidrokimia (anion-kation) dan isotop alam (d²H, d¹⁸O) menunjukkan bahwa air-tanah dalam masih mencerminkan karakter sebagai air-tanah segar atau freshwater. Air-tanah akuifer dalam juga terindikasi tidak berhubungan dengan air-tanah akuifer dangkal yang berada di atasnya. Air-tanah dangkal, sebagian besar masih menunjukkan karakter air-tanah segar dan sebagian lainnya, yaitu SB-8, SB-9, dan SB-10, air-tanahnya mengalami pertukaran ion dan interaksi dengan air permukaan. Air permukaan untuk SB-8 diperkirakan berasal dari rembesan larutan pupuk tanaman sedangkan untuk SB-9 dan SB-10 air permukaan diperkirakan berasal dari rembesan tanki kotoran (septic tank).

Groundwater research has been conducted in Nuclear Area of Pasar Jumat (KNPJ) using hydrochemical data and natural isotopes methods. The research was conducted by taking a number of water samples in some areas of KNPJ and also its surrounding areas. The water samples were then analyzed its hydrochemical concentration (anion-cation) and natural isotope concentration d²H and d¹⁸O using lasser counter device. Water chemical analysis was conducted by using ion chromatography and titration methods. The purpose of this research is to know the characteristics of groundwater to the possibility of its interaction with the surrounding surface water. Based on the results of hydrochemical analysis (anion-cation) and natural isotopes (d²H, d¹⁸O) indicates that groundwater still reflects the character as fresh groundwater or freshwater. The deep aquifer groundwater is also indicated to be unrelated to groundwater of shallow aquifers located above it. While most shallow groundwater still show the character of fresh groundwater, and some others namely SB-8, SB-9, and SB-10, the groundwater undergo ion exchanges and interact with surface water. Surface water for SB-8 is estimated come from the seepage of the liquid plant fertilizer, whereas for SB-9 and SB-10 surface water is estimated come from septic tank seepage.

[1] Satrio dan P. Sidauruk, “Studi Daerah Imbuh Sistem Air Sungai Bawah Tanah Gunungkidul Yogyakarta Menggunakan Isotop Stabil ¹⁸O dan ²H”, J. Ilm. Apl. Isot. dan Radiasi, vol. 12, no. 1, 2015.

[2] Satrio, Hendarmawan, M. S. D. Hadian, dan E. R. Pujiindiyati, “Karakteristik Airtanah Dangkal Kota Semarang pada Musim Penghujan Berdasarkan Pendekatan Isotop Stabil (¹⁸O, ²H) dan Kimia Air”, J. Ilm. Apl. Isot. dan Radiasi, vol. 11, no. 1, pp. 73–86, 2015.

[3] A. H. Cheng and P. Sidauruk, “A Groundwater Flow Mathematica Tool Package”, Groundwater, 34 (1), pp. 41–48, 1998.

[4] H. Tirtomihardjo, “Airtanah dan Pembangunan Bawah Tanah Jakarta”, Geomagz, 28 Januari 2014, [Online]. Tersedia: http://geomagz.geologi.esdm.go.id/air-tanah-dan-pembangunan-bawah-tanah-jakarta.

[5] H. L. Kharisma, A. B. Wijatna, dan W. Wilopo, “Aplikasi Isotop Alam untuk Mengetahui Asal-Usul Air Umbul Cokro, KecamatanTulung, Kabupaten Klaten”, Forum Teknik, vol. 36, no. 11, pp. 73–80, 2015.

[6] Satrio, Syafalni, dan P. Sidauruk, “Studi Karakteristik Airtanah Dangkal Sekitar TPST Bantar Gebang, Bekasi dengan Metode Sumur Tunggal dan Ganda”, J. Ilm. Apl. Isotop dan Radiasi, vol. 10, no.1, pp. 1–10, 2014.

[7] N. Laksminingpuri dan Satrio, “Aplikasi Isotop Stabil δ²H dan δ¹⁸O untuk Studi Airtanah di Kawasan PPTN Pasar Jumat”, in Prosiding Seminar Nasional Pendayagunaan Teknologi Nuklir, PRFN-BATAN, pp. 63–69, 2016.

[8] B. Sharma, R. Singh, P. Singh, D. P. Uniyal, and R. Dobhal, “Water Resources Management Through Isotope Technology in Changing Climate”, American Journal of Water Resources, vol. 3, no. 3, pp. 86–91, 2015, DOI: 10.12691/ajwr-3-3-3.

[9] Y. Mtoni, I. C. Mjemah, C. Bakundukize, M. V. Camp, K. Martens, and K. Walraevens, “Saltwater Instrusion and Nitrate Pollution in The Coastal Aquifer of Dar Es Salaam, Tanzania”, Environ Earth Sci, vol. 70 (3), pp 1091–1111, 2013, DOI 10.1007/s12665-012-2197-7.

[10] Satrio dan R. P. I. Evarista, “Karakteristik Airtanah Akuifer Dalam Sekitar Tempat Pembuangan Sampah Terpadu (TPST) Bantar Gebang-Bekasi, Jawa Barat”, Jurnal Teknologi Lingkungan, vol. 18, no. 1, pp. 96–103, 2017.

[11] S. M. Yidana, “The Stable Isotope Characteristics of Groundwater in The Voltain Basin-An Evaluation of The Role of Meteoric Recharge in The Basin”, J. Hydrogeol. Hydrol. Eng., vol. 2, no.2, pp. 1–10, 2013.

[12] S. B. Muhammad and U. Sadiq, “Analysis of Stable Isotopic Composition of Precipitation in Katsina State in Nigeria As an Indication of Water Cycle”, Adv. Phys. Theor. Appl., vol. 33, pp. 28–34, 2014.

[13] N. Hendrikson, J. Karhu, and P. Niinikoski, “¹⁸O, ²H, and ³H Isotopic Composition of Precipitation and Shallow Groundwater in Olkiluoto”, Posiva OY, FI-27160 EURAJOKI, Finland, 2014.

[14] Allen, J. R. Brooks, R. F. Keim, B. J. Bon, and J. J. McDonnel, “The Role of Pre-Event Canopy Strorage in Throughfall and Stemflow by Using Isotpic Tracers”, Ecohydrology, 2013. DOI: 10.1002/eco.1408.

[15] R. T. Andihutomo, Satrio, R Prasetio, dan A. B. Wijatna “Studi Interaksi Airtanah Dangkal dan Air Sungai di Sepanjang Daerah Aliran Kali Garang Semarang Menggunakan Isotop Stabil δ¹⁸O dan δ²H”, J. Eksplorium, vol. 38, no. 1, pp. 43–48, 2017.

[16] A. P. Uzoije, A. Onunkwo-A., C. C. Uche, and Ashiegbu, “Evaluation of Groundwater Quality of Coastal Aquifer Systems in Buguma City”, Rivers State South-Southern Nigerian Civil and Environmental Research, vol.6, no.7, 2014.

[17] A. K. Singh and S. R. Kumar, “Quality assessment of groundwater for drinking and irrigation use in semi-urban area of Tripura, India”, Ecology, Environment and Conservation, 21 (1), pp. 97–108, 2015.

[18] L. Xing, H. Guo, and Y. Zhan, “Groundwater hydrochemical characteristics and processes along flow path in the North China Plain”, Journal of Asian Earth Sciences, 70-71, pp. 250–264, 2013.

[19] E. A. P. Gonti, A. B. Wijatna, dan Satrio, “Studi Interrelasi Airtanah dan Air Lindi di Sekitar TPST Piyungan Yogyakarta”, in Prosiding Seminar Nasional Teknologi Pengelolaan Limbah XV, PTLR-BATAN dan Sekolah Ilmu Lingkungan-UI, 2017.