Two-Dimensional Modeling of Leachate Distribution in Batu Layang Landfill on Peat Soil using Geoelectric Method

Fitriana Meilasari; Hendri Sutrisno; Arifin Arifin; Rizki Purnaini; Irda Dwi Utari

doi:10.14710/presipitasi.v20i3.633-643

DOI: https://doi.org/10.14710/presipitasi.v20i3.633-643

Two-Dimensional Modeling of Leachate Distribution in Batu Layang Landfill on Peat Soil using Geoelectric Method

*Fitriana Meilasari - Universitas Tanjungpura, Indonesia

Hendri Sutrisno - Universitas Tanjungpura, Indonesia

Arifin Arifin - Universitas Tanjungpura, Indonesia

Rizki Purnaini - Universitas Tanjungpura, Indonesia

Irda Dwi Utari - Universitas Tanjungpura, Indonesia

BibTex Citation Data :

@article{Presipitasi57557,
    author = {Fitriana Meilasari and Hendri Sutrisno and Arifin Arifin and Rizki Purnaini and Irda Utari},
    title = {Two-Dimensional Modeling of Leachate Distribution in Batu Layang Landfill on Peat Soil using Geoelectric Method},
    journal = {Jurnal Presipitasi : Media Komunikasi dan Pengembangan Teknik Lingkungan},
  volume = {20},
    number = {3},
    year = {2023},
    keywords = {Batu Layang landfill, geoelectricity, leachate},
    abstract = {  The open dumping system implemented by the Batu Layang landfill can produce leachate, contaminating groundwater around the landfill. Groundwater contaminated with leachate, if used by the community, can cause health problems. Therefore, management efforts were needed, such as subsurface leachate modeling. This study aims to model the distribution of subsurface leachate in 2 dimensions. The modeling of leachate distribution below the soil surface used the Wenner configuration geoelectric method. The number of geoelectric measurement paths was two paths. The length of each track was 195 m, with a distance of 5 m between the electrodes. Data obtained from resistivity values were analyzed using the Res2Dinv application. The calculation of leachate discharge used the water balance method. Based on the inversion results using the Res2Dinv software, the resistivity value of leachate-contaminated soil in line 1 was 1.19-9.43 Ωm, and track 2 was 0.5-10.2 Ωm. The leachate resistivity value was <10 Ωm because the leachate contains inorganic minerals (metals), so the resistivity value was low. Land contaminated with leachate was estimated to be spread as far as 195 m. The most profound leachate depth was estimated at 39.4 m. Batu Layang Landfill leachate discharge in Zone E averages 4 m 3 /day.  },
   issn = {2550-0023},   pages = {633--643}  doi = {10.14710/presipitasi.v20i3.633-643},
    url = {https://ejournal.undip.ac.id/index.php/presipitasi/article/view/57557}
}

Citation Format:

Abstract

The open dumping system implemented by the Batu Layang landfill can produce leachate, contaminating groundwater around the landfill. Groundwater contaminated with leachate, if used by the community, can cause health problems. Therefore, management efforts were needed, such as subsurface leachate modeling. This study aims to model the distribution of subsurface leachate in 2 dimensions. The modeling of leachate distribution below the soil surface used the Wenner configuration geoelectric method. The number of geoelectric measurement paths was two paths. The length of each track was 195 m, with a distance of 5 m between the electrodes. Data obtained from resistivity values were analyzed using the Res2Dinv application. The calculation of leachate discharge used the water balance method. Based on the inversion results using the Res2Dinv software, the resistivity value of leachate-contaminated soil in line 1 was 1.19-9.43 Ωm, and track 2 was 0.5-10.2 Ωm. The leachate resistivity value was <10 Ωm because the leachate contains inorganic minerals (metals), so the resistivity value was low. Land contaminated with leachate was estimated to be spread as far as 195 m. The most profound leachate depth was estimated at 39.4 m. Batu Layang Landfill leachate discharge in Zone E averages 4 m³/day.

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Keywords: Batu Layang landfill, geoelectricity, leachate

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Section: Regional Case Study

Language : EN

In Vol 20, No 3 (2023): November 2023

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Abdel-Shafy, H.I., Ibrahim, A.M., Al-Sulaiman, A.M., Okasha, R.A., 2023. Landfill leachate: Sources, nature, organic composition, and treatment: An environmental overview. Ain Shams Engineering. Journal. 102293
Abrauw, A.E.S., 2019. Studi Operasional Pengelolaan Limbah Cair Lindi (Leachate) Pada Tpa Control Landfill Koya Koso. J. Din. 1, 1–10
Amien, S., 2016. Penyelidikan Hidrogeologi Dengan Metode Geolistrik Schlumberger di Kecamatan Hamparan Perak, Deli Serdang, Sumatera Utara. Journal of Electrical Engineering Volume 1
Apriasti, E.R., Marsudi, Utomo, kiki P., 2016. Pola Sebaran Air Lindi Di Tpa Batu Layang Pontianak Dengan Metode Geolistrik Wenner-Schlumberger. Jurnal Teknologi Lingkungan Lahan Basah 4, 1–10
Arman, Y., 2012. Identifikasi Struktur Bawah Tanah di Kelurahan Pangmilang Kecamatan Singkawang Selatan Menggunakan Metode Geolistrik Resistivitas dan Inversi Lavenberg - Marquardt. POSITRON 2, 6–11
Arrazi, H.F., Usman, 2021. Interpretasi Lapisan Bawah Permukaan TPA Muara Fajar Untuk Mengetahui Pola Sebaran Lindi Dengan Menggunakan Metode Geolistrik Konfigurasi. Wenner. Repos. Umr. 1–9
Asmaranto, R., 2012. Identifikasi Air Tanah (Groundwater) Menggunakan Metode Resistivity (Geolistrik With Ip2win Software). Fakultas Teknik Universitas Brawijaya
Astuti, Y., Astiani, D., Herawatiningsih, R., 2020. Pengaruh Pembakaran Berulang Pada Lahan Gambut Terhadap Beberapa Karakteristik Tanah Di Desa Rasau Jaya Umum Kabupaten Kubu Raya Kalimantan Barat. JURNAL HUTAN LESTARI 8, 668–681
Azis, A., Yusuf, H., Badaruddin, S., 2018. Efektivitas Kolom Pasir Pada Waduk Resapan Sebagai Penyangga. pp. 43–48
Aziz, R., Ihsan, T., Permadani, A.S., 2019. Skenario Pengembangan Sistem Pengelolaan Sampah Kabupaten Pasaman Barat dengan Pendekatan Skala Pengolahan Sampah di Tingkat Kawasan dan Kota. Jurnal Serambi Engineering. 4, 444
Biaggi, M.., 2022. Pengaruh Hujan Terhadap Konsentrasi Logam Dalam Sedimen Sungai Code. Universitas Islam Indonesia
Dinas Lingkungan Hidup (DLH) Kota Pontianak, 2022. Jumlah Timbulan Sampah Tahun 2022. Pontianak
Direktorat Pengembangan Penyehatan Lingkungan Permukiman, 2018. Tata Cara Perencanaan dan Pembangunan Tempat Pemrosesan Akhir (TPA) Sampah. Jakarta
Dzulfahmi, D., Ivansyah, O., Zulfian, Z., 2019. Monitoring Pergerakan Lindi Menggunakan Metode Geolistrik Time-Lapse Di Sekitar Pemukiman Tempat Pembuangan Akhir Batu Layang Pontianak. Prism. Fis. 7, 251
Fajania, R., Arman, Y., Muhardi, M., 2021. Pendugaan Ketebalan Lapisan Gambut Di Sekitar Jalan Reformasi Kota Pontianak Menggunakan Metode Geolistrik Tahanan Jenis. Jurnal GEOCELEBES 5, 16–22
Fang, D., Wang, J., Cui, D., Dong, X., Tang, C., Zhang, L., Yue, D., 2021. Recent Advances of Landfill Leachate Treatment. Journal of the Indian Institute of Science. 101, 685–724
Hakim, A.R., Susilo, A., Maryanto, S., 2014. Spread Indication of Underwater Surface Contaminants Using Magnetic Method (Case Study: TPA Supit Urang, Malang). Natural-B 3, 281–289
Hakim, H., Manrulu, R.H., 2016. Aplikasi Konfigurasi Wenner dalam Menganalisis Jenis Material Bawah Permukaan. Jurnal Ilmu Pendidikan Fisika Al-Biruni 5, 95–103
Jakarius, Muliadi, Zulfian, 2021. Studi Sifat Fisika Pada Tanah Gambut di TPA Batu Layang Berdasarkan Tingkat Kematangan Tanah Gambut. Prism. Fis. 9, 166–171
Jaya, A.E.S., Suarna, I.W.I.W., Aryanta, I.W.R., 2016. Studi Kualitas Air Tanah Dangkal Dan Pendapat Masyarakat Sekitar Tempat Pemrosesan Akhir Sampah Suwung Kecamatan Denpasar Selatan, Kota Denpasar. ECOTROPHIC Jurnal Ilmu Lingkungan, 62
Maryani, I., Marsudi, Nasrullah, 2016. dentifikasi Penggunaan Sumber Air Baku oleh Penduduk di Sekitar TPA Batulayang Pontianak. Jurnal Teknologi Lingkungan Lahan Basah 4
Miswar, 2017. Metode Geolistrik Resistivitas Di Kawasan Industri Makassar (KIMA). UIN Alauddn Makasar
Muhardi, M., Muliadi, M., Zulfian, Z., 2020. Model 3D Sebaran Lindi pada Lapisan Tanah di Area TPA Batulayang Pontianak Berdasarkan Nilai Resistivitas. Jurnal Fisika Flux: Jurnal Ilmiah Fisika FMIPA Univ. Lambung Mangkurat 17, 72
Muliadi, M., Zulfian, Z., Muhardi, M., 2019. Identifikasi Ketebalan Tanah Gambut Berdasarkan Nilai Resistivitas 3D: Studi Kasus Daerah Tempat Pembuangan Akhir Batu Layang Kota Pontianak. POSITRON 9, 86
Padilah, H., Widyaningrum, Y., Kurniawan, widodo budi, 2021. Identifikasi Sebaran Air Lindi (Leachate) Menggunakan Metode Geolistrik Self-Potential (SP) Di Tempat Pembuangan Akhir (TPA) Parit Enam Kota Pangkalpinang. Jurnal Riset Fisika Edukasi dan Sains 2, 15–24
Pratiwi, D.P., Susanti, N., Dewi, I.K., 2018. Penerapan Metode Geolistrik Konfigurasi Wenner Mapping Untuk Mengetahui Rembesan Air Lindi Di TPA Talang Gulo Jambi. JoP 4, 18–22
Purba, D.C.V., Kamil, I.M., 2015. Analisis Pola Penyebaran Logam Berat Pada Air Tanah Dangkal Akibat Lindi Di Sekitar Tempat Pemrosesan Akhir (TPA) Jatibarang, Semarang. Jurnal Teknologi Lingkungan 21, 149–158
Qadri, U., Wahyuni, R., Listiyawati, L., 2020. Inovasi Manajemen Pengelolaan Sampah yang Berwawasan Lingkungan di Kota Pontianak berbasis Aplikasi. Eksos 16, 144–160
Ramadhan, F., Prasasti D.R, F., Firizqy, F., Nugroho Adji, T., 2019. Pendugaan Distribusi Air Lindi dengan Geolistrik Metode ERT di TPA Piyungan, Bantul, DIY. Majalah Geografi Indonesia 33, 1
Ramadhaningsih, L., Sampurno, J., 2017. Identifikasi Struktur Lapisan Bawah Permukaan Lahan Gambut di Desa Arang Limbung Kecamatan Sungai Raya Kabupaten Kubu Raya dengan Metode Resistivitas Konfigurasi Dipole-Dipole. Physics Community. 1, 29–35
Ratih, Y.I., Suaidi, D.A., Hidayat, S., 2021. Identifikasi arah rembesan lindi menggunakan metode geolistrik resistivitas konfigurasi dipole-dipole di sekitar tempat pembuangan akhir (TPA) sampah sekoto kabupaten Kediri. Jurnal MIPA dan Pembelajarannya 1, 624–633
Sampurno, J., Muid, A., Zulfian, Latief, F.D.E., 2018. Characterization The Geometry Of The Peat Soil Of Pontianak Using Fractal Method. Journal of Physics: Conference. Series 1040, 012044
Sari, E.K., Lucyana, L., 2021. Evaluasi Instalasi Pengolahan Air Lindi Di Tempat Pembuangan Akhir Sampah (TPAS) Simpang Kandis Kabupaten Ogan Komering Ulu. J. Deform. 6, 33
Shah, A. V., Singh, A., Sabyasachi Mohanty, S., Kumar Srivastava, V., Varjani, S., 2022. Organic solid waste: Biorefinery approach as a sustainable strategy in circular bioeconomy. Bioresource Technology 349, 126835
Simanjuntak, H.R., Surbakti, A., 2021. Penentuan Sebaran Lindi Dengan Menggunakan Metode Geolistrik Konfigurasi Wenner Dan Uji Geokimia Di TPA Muara Fajar. Universitas Riau
Sukisna, Toifur, M., 2019. Penentuan Konduktivitas Air Baku Proses Desilinasi di Baron Teknopark dengan Metode Regresi Linier. J. Mater. dan Pembelajaran Fis. 9, 127–131
Suwarna, N., Langford, R.., 1993. Peta Geologi Lembar Singkawang. Bandung
Telford, W., Geldart, P., Sheriff, E., Keys, A., 1990. Applied Geophysics. Cambridge University Press, New York
Wibowo, H., 2010. Laju Infiltrasi pada Lahan Gambut yang Dipengaruhi Air Tanah (Study Kasus Sei Raya Dalam Kecamatan Sei Raya Kabupaten Kubu Raya). Jorunal of Belian 9, 90–103
Wu, C., Chen, W., Gu, Z., Li, Q., 2021. A review of the characteristics of Fenton and ozonation systems in landfill leachate treatment. Science of the Total Environment. 762, 143131
Yatim, E.M., Mukhlis, 2013. Pengaruh Lindi ( Leachate ) Sampah Terhadap Air Sumur Penduduk Sekitar Tempat Pembuangan Akhir ( Tpa ) Air Dingin. Jurnal Kesehatan Masyarakat. 7, 54–59
Zulkifley, M.T.M., Ng, T.F., Raj, J.K., Hashim, R., Ghani, A., Shuib, M.K., Ashraf, M.A., 2013. Definitions and engineering classifications of tropical lowland peats. Bulletin of Engineering Geology and the Environment. 72, 547–553

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