The peak of the rainy season in 2022/2023 has caused many disasters, especially landslides in Indonesia, which have claimed many victims and caused damage to settlements and infrastructure. Various geophysical methods have been widely applied to identify slip fields. In addition, geophysical methods are used to determine the type and characteristics of landslides. The slip field has a lithology of 2 subsurface layers of soil or contrasting rocks, namely soft and hard soil layers. Therefore, one of the geophysical methods that is effective in identifying slip planes is the geoelectric method because of the stark contrast in resistivity in the two soil layers. This article will review research that uses geoelectric data to survey landslide potential in the last ten years. In addition, this article also reviews the latest research related to geoelectricity, namely Time-Lapse Electrical Resistivity Tomography (TL-ERT), starting from studies that have used this method and the potential and direction of using this method in the future.

Adhe, A. (2022). Perbandingan Hasil Deteksi Air Tanah Dengan Metode Geolistrik Konfigurasi Schlumberger, Wenner, Wenner-Schlumberger, Dipole-Dipole, dan Pole-Pole. Prosiding Seminar Nasional ReTII ke-17.

Akmam, Amir, H., Putra, A., Anshari, R., & Jalinus, N. (2019). Implementation of least-square constrains inversion method of geoelectrical resistivity data Wenner-Schlumberger for investigation of landslide characteristics. Journal of Physics: Conf. Series, 1185(1). 10.1088/1742-6596/1185/1/012013

Angga, A., Feranie, S., Tohari, A., & Latief, F. (2016). Karakterisasi Lereng Berpotensi Longsor Serta Upaya Mitigasi Bencananya: Studi Kasus Di Badan Jalan Lembang Dan Cijambe-Subang. Prosiding Seminar Nasional Fisika (E-Journal), 5.

Aryanto, R., Indriastuty, D., Azizi, M. A., & Sumarjono, E. (2020). Analisis Tinggi Muka Air Tanah Pada Daerah Longsoran Serta Pengaruhnya Terhadap KEstabilan Lereng Dengan Metode Geolistrik di Bukit Kaliwadas, Kedungwaru Karangsambung Jawa Tengah. Prosiding Seminar Nasional Pakar ke-3 Tahun 2020. doi.org/10.25105/pakar.v0i0.6776

Binley, A., Henry-Poulter, S., & Shaw, B. (1996, April). Examination of solute transport in an undisturbed soil column using electrical resistance tomography. Water Resources Research, 32(4), 763-769. doi.org/10.1111/j.1745-6584.1997.tb00103.x

Blanchy, G., Huntenburg, K., Hawkesford, M., & Watts, C. (2020). Time-Lapse Geophysical Assessment Of Agricultural Practices On Soil Moisture Dynamics. Vadose Zone Journal, 19(1).

BMKG. (2023). Buletin Informasi Iklim Maret. Badan Meteorologi Klimatologi dan Geofisika.

Bouvier, C., Adamovic, M., Ayral, P.-A., Brunet, P., Didon-Lescot, J.-F., Domergue, J.-M., & Spinelli, R. (2021). Characterization of subsurface fluxes at the plot scale during flash floods in the Valescure catchment, France. Hydrological Processes, 35. doi.org/10.1002/hyp.14144

Carlo, L. D., Battilani, A., Solimando, D., & Clementina, M. (2020). Application Of Time-Lapse Ert To Determine The Impact Of Using Brackish Wastewater For Maize Irrigation. Journal of Hydrology. 10.1016/j.jhydrol.2019.124465

Conaway, C. H., Johnson, C. D., Lorenson, T. D., Turetsky, M., Euskirchen, E., Waldrop, M. P., & Swarzenski, P. W. (2020). Permafrost Mapping with Electrical Resistivity Tomography: A Case Study in Two Wetland Systems in Interior Alaska. Journal of Environmental and Engineering Geophysics, 25(2), 199-209. http://doi.org/10.2113/JEEG19-091

Di Giuseppe, M. G., & Troiano, A. (2019). Monitoring active fumaroles through time-lapse electrical resistivity tomograms: an application to the Pisciarelli fumarolic field (Campi Flegrei, Italy). Journal of Volcanology and Geothermal Research, 375, 32-42. doi.org/10.1016/j.jvolgeores.2019.03.009

Firmansyah, Feranie, S., Tohari, A., & Latief, F. (2015). Prediksi Jangkauan Pergerakan Tanah Longsor Menggunakan Model Gesekan Coulomb Sederhana. Prosiding Simposium Nasional Inovasi dan Pembelajaran Sains, 1(1).

Fishkis, O., Noell, U., Diehl, L., & Jaquemotte, J. (2020). Geoderma Multitracer Irrigation Experiments For Assessing The Relevance Of Preferential Flow For Non-Sorbing Solute Transport In Agricultural Soil. Geoderma. 10.1016/j.geoderma.2020.114386

Folch, A., del Val, L., Luquot, L., & Martínez-Pérez, L. (2020). Combining Fiber Optic Dts, Cross-Hole Ert And Time-Lapse Induction Logging To Characterize And Monitor A Coastal Aquifer. Journal of Hydrology. 10.1016/j.jhydrol.2020.125050

Gunawan, M. S., Yuliadi, & Guntoro, D. (2022). Identifikasi Zona Rawan Longsor Menggunakan Analisis Probabilitas Kelongsoran pada Lereng Alami dengan Metode Kesetimbangan Batas (Limit Equilibrium Method). Bandung Conference Series: Mining Engineering, 2(1), 10 - 18. doi.org/10.29313/bcsme.v2i1.805

Hendri, Faryuni, I. D., & Zulfian. (2019). Identifikasi Bidang Gelincir dan Tipe Tanah Longsor di Daerah Rawan Longsor Desa Bantai Menggunaan Metode Geolistrik. PRISMA FISIKA, 7(3), 167 - 174. dx.doi.org/10.26418/pf.v7i3.36329

Jodry, C., Lopes, S. P., Fargier, Y., Sanchez, M., & Côte, P. (2019). 2D-ERT monitoring of soil moisture seasonal behaviour in a river levee: A case study. Journal of Applied Geophysics, 167, 140-151. doi.org/10.1016/j.jappgeo.2019.05.008

Jufriadi, A., & Ayu, H. D. (2014, Agustus). Aplikasi Geolistrik Resistivitas untuk Mengetahui Distribusi Tahanan Jenis dalam Investigasi Potensi Bencana Longsor di Perbukitan Ampelgading Kabupaten Malang. FOTON, 18(2), 15 - 20.

Khoiriyah, T. M., Feranie, S., & Tohari, A. (2016, Desember). STUDI PARAMETRIK PENGARUH POLA CURAH HUJAN terhadap JARAK JANGKAUAN (RUN-OUT) LONGSOR di LEMBANG-BANDUNG. Spektra: Jurnal Fisika dan Aplikasinya, 1(2), 129-136. doi.org/10.21009/SPEKTRA

Lapenna, V., & Perrone, A. (2022). Time-Lapse Electrical Resistivity Tomography (TL-ERT) for Landslide Monitoring: Recent Advances and Future Directions. Applied Sciences, 12(3). doi.org/10.3390/app12031425

Makhrani. (2013). Optimalisasi Desain Parameter Lapangan Untuk Data Resistivitas Pseudo 3D. Positron, 3(1).

Mollaret, C., Hilbich, C., Pellet, C., Flores-Orozco, A., Delaloye, R., & Hauck, C. (2019). Mountain permafrost degradation documented through a network of permanent electrical resistivity tomography sites. The Cryosphere, 13, 2557-2578. doi.org/10.5194/tc-13-2557-2019

Oyeyemi, K. D. (2022). Assessing the suitable electrical resistivity arrays for characterization of basement aquifers using numerical modeling. Heliyon, 8(5).

Palacios, A., José Ledo, J., Linde, N., & Luquot, L. (2020). Time-Lapse Cross-Hole Electrical Resistivity Tomography (Chert) For Monitoring Seawater Intrusion Dynamics In A Mediterranean Aquifer. Hydrology and Earth System Sciences, 24(4). 10.5194/hess-24-2121-2020

Paz, M. C., Alcalá, F. J., & Medeiros, A. (2020). Integrated Masw And Ert Imaging For Geological Definition Of An Unconfined Alluvial Aquifer Sustaining A Coastal Groundwater-Dependent Ecosystem In Southwest Portugal. Applied Sciences (Switzerland), 10(17). 10.3390/app10175905

Pazha, H. (2019). Analysis of Rock Structures Based on Geoelectrical Resistivity Data of Wenner-Alpha Configuration Using Marquardt's Inversion Method. Journal of Physics: Conference Series, 1175(1).

Rizkianti, C., Feranie, S., & Tohari, A. (2019). The Effect of Earthquake to Stability and Run Out Distance of Landslide During Rainfall: a case study of landslide-prone area in West Java, Indonesia. Journal of Physics: Conference Series, 1204(1). :10.1088/1742-6596/1204/1/012108

Rizky, A. (2015). Pemanfaatan Data Electrical Resistivity Tomography Dalam Analisis Stabilitas Bendungan Selorejo Terhadap Beban Gempa. Universitas Brawijaya.

Scandroglio, R., Draebing, D., Offer, M., & Krautblatter, M. (2021). 4D quantification of alpine permafrost degradation in steep rock walls using a laboratory-calibrated electrical resistivity tomography approach. Near Surface Geophysics, 19, 241-260. http://doi.org/10.1002/nsg.12149

Sitepu, F. (2017). Pengaruh Intensitas Curah Hujan dan Kemiringan Lereng Terhadap Erosi yang Berpotensi Longsor. Jurnal Penelitian Enjiniring.

Slater, L., Binley, A., Versteeg, R., Cassiani, G., Birken, R., & Sandberg, S. (2002). A 3d Ert Study Of Solute Transport In A Large Experimental Tank. Journal of Applied Geophysics.

Srivastava, S., Kumar, S., & Rajwardhan, P. (2020). A Time ‑ Lapse Study Using Self ‑ Potential And Electrical Resistivity Tomography Methods For Mapping Of Old Mine Working Across Railway ‑ Tracks In A Part Of Raniganj Coalfield , India. Environmental Earth Sciences, 79(13), 1-19. 10.1007/s12665-020-09067-3

Susilo, A., Sunaryo, Juwono, A. M., Fitriah, F., Puspita, M. B., Hasan, M. F. R., Hisyam, F., & Suryo, E. A. (2022). Teori dan Aplikasi Metode Geolistrik Resistivitas. Universitas Brawijaya Press.

Suyanto, Y. D. A. (2017). Evaluasi Stabilitas Lereng Faktor Pemicu Topografi Dan Geologi Dengan Metode Resistivitas Studi Kasus : Longsor Di Kota Semarang. UNNES.

Tejakusuma, I. G., Khaerani, P., Trisnafiah, S., Shomim, A. F., Wisyanto, & Naryanto, H. S. (2020, Juni). Penentuan Bidang Gelincir Longsor Dengan Analisis Geologi dan Geolistrik di Gunung Geger Pulus Segmen Lereng Legok Emo, Cililin, Jawa Barat. Jurnal Sains dan Teknologi Mitigasi Bencana, 15(1), 63 - 73. doi.org/10.29122/jstmb.v15i1.4114

Tso, C.-H. M., Johnson, T. C., Song, X., Chen, X., Kuras, O., Wilkinson, P., Uhlemann, S., Chambers, J., & Binley, A. (2020). Integrated hydrogeophysical modeling and data assimilation for geoelectrical leak detection. Journal of Contaminant Hydrology, 234. doi.org/10.1016/j.jconhyd.2020.103679

Tunena, M., As'ari, A., & Tamumtuan, G. H. (2018). Identifikasi Bidang Gelincir Dengan Eksplorasi Geolistrik Dalam Upaya Mitigasi Bencana Alam Tanah Longsor Di Desa Tinoor. Jurnal MIPA, 7(2), 1-5. doi.org/10.35799/jm.7.2.2018.20616

Utiya, J. (2015). Metode Geolistrik Restivitas Konfigurasi Wenner-Schlumberger Dan Konfigurasi Dipole-Dipole Untuk Identifikasi Patahan Manado Di Kecamatan Paaldua Kota Manado. Jurnal Ilmiah Sains, 17(1).

Vebrianto, S. (2016). Eksplorasi Metode Geolistrik. Universitas Brawijaya Press.

Zuhdi, M., Taufik, M., Ayub, S., Wahyudi, & Makhrus, M. (2021). Pengantar Geofisika. Penerbit Einstein College.