BOUGUER ANOMALY AND SEDIMENT THICKNESS ESTIMATION AT THE TEHORU GEOTHERMAL AREA
DOI:
https://doi.org/10.23960/jge.v12i1.512Keywords:
Bouguer Anomaly, Reduced-Bouguer density, Sediment Thickness, Tehoru Geothermal Area, TOPEX GravityAbstract
Tehoru Village, Tehoru District, Central Maluku Regency, has significant geothermal potential. This study aims to examine Bouguer anomalies, reduced-Bouguer density, sediment thickness estimation, and shallow structures using TOPEX gravity data and SRTM DEM in an area of ±191.70 km². The processing results show Complete Bouguer Anomaly (CBA) values ranging from 6.80 to 73.60 mGal, with Bouguer densities of 1.77 to 1.79 g/cm³, indicating the dominance of alluvial sediments. Anomaly separation using the Moving Average method yields residual anomalies ranging from -4.60 to 47.70 mGal, with low anomalies dominant in the southwest of the geothermal manifestation. Spectral analysis shows an average sediment thickness of ±246.07 m. In contrast, SVD analysis, lineament maps, and rose diagrams indicate that geothermal manifestations develop in tight fault-related zones with a dominant northeast–southwest orientation. Although effective for regional analysis, TOPEX gravity data interpretation has limitations for imaging shallow structures and sediment thickness variations, as small anomalies are often obscured by its relatively low spatial resolution. Overall, the Tehoru geothermal system is controlled by several local fault-related zones and significant sediment thickness, which influence its response to tectonic activity.
References
Abdelrahman, E. M. & El-Araby, T. M. (1996). Shape and Depth Solutions From Moving Average Residual Gravity Anomalies. Journal of Applied Geophysics, Vol. 36.
Abdullahi, M. (2022). Gravity Anomaly and Basement Estimation Using Spectral Analysis. https://doi.org/10.5772/intechopen.99536
Andayany, H. & Risakotta, M. Y. S. (2017). Application of Geotermometry Equation (SiO2)p in The Geothermal Areas Both Haruku and Tehoru, Central of Maluku. International Journal of Health Medicine and Current Research, 2(04), 605–609. https://doi.org/10.22301/IJHMCR.2528-3189.605
Armi, R. (2025). Spectral Analysis in the Separation of Gravity Anomalies: Implications for Disaster Risk Reduction in the West Coast of Aceh. Earth Sciences Research Journal, 29(4), 399–407. https://doi.org/10.15446/esrj.v29n4.116923
Blakely, R. J. (1996). Potential Theory in Gravity and Magnetic Applications (1st ed., Vol. 1). Cambridge University Press. https://doi.org/https://www.eoas.ubc.ca/academics/courses/eosc450/ewExternalFiles/Blakely_PotentialFieldsText.pdf
Daniarsyad, G., Priyobudi, P., Cahyaningrum, A. P., Wibisono, D. G., Sriyanto, S. P. D., Rosid, A., Pranata, B., Gunawan, I., Fatchurochman, I., & Daryono, D. (2023). Analysis on the Causative Fault of the 2021 Mw 6.0 Tehoru Earthquake in the South Coast of Seram Island: A Preliminary Result. E3S Web of Conferences, 447. https://doi.org/10.1051/e3sconf/202344701020
Dewanto, B. G., Margiono, R., Segoro, Y. A., Pramesthi, E., & Maimuna, A. K. (2023). The Importance of Gravity Data For Estimating and Identifying The Sediment Thickness of Subsurface Structure Around Majene Sulawesi Barat. AIP Conference Proceedings, 2654. https://doi.org/10.1063/5.0115361
Directorate of Geothermal Energy (2017). Potential Geothermal Indonesia Vol. 1 (1st ed., Vol. 2). Directorate General of New, Renewable Energy and Energy Conservation, Ministry of Energy and Mineral Resources. https://www.esdm.go.id/en/berita-unit/directorate-general-ebtke/peluncuran-buku-potensi-panas-bumi-indonesia-2017
Elkins, T. A. (1951). The Second Derivative Method of Gravity Interpretation. 06(1), 29–50. https://doi.org/10.1190/1.1437648
Gunawan, H., & Mikhailov, V. (2008). Estimation of Bouguer Density Precision: Development of Method for Analysis of La Soufriere Volcano Gravity Data. Jurnal Geologi Indonesia (Vol. 3, Number 3).
Hill, K. C. (2012). Tectonic and Regional Structure of Seram and the Banda Arc. Indonesian Journal of Sedimentary Geology, 23(1), 5–61. https://doi.org/https://doi.org/10.51835/bsed.2012.23.1.187
Ilham, Susilo, A., Sukanta, I. N., Siregar, D. V., Hasan, M. F. R., & Hardianto, Y. P. (2025). Detecting Active Fault with the Topographic Gravity Model: A Case Study from Turen, Indonesia. Iraqi Geological Journal, 58(2), 203–215. https://doi.org/10.46717/igj.2025.58.2A.13
Maringue, J., Sáez, E., & Yañez, G. (2021). An Empirical Correlation Between The Residual Gravity Anomaly and The H/V Predominant Period in Urban Areas and Its Dependence on Geology in Andean Forearc Basins. Applied Sciences (Switzerland), 11(20). https://doi.org/10.3390/app11209462
Nettleton, L.L. (1939). Determination of Density For Reduction of Gravimeter Observations. Geophysics, 4(3), 176–183. https://doi.org/https://doi.org/10.1190/1.1437088
Pelupessy, W. V., & Silverman, R. M. (2024). Exploring Indonesian Coastal Communities’ Responses To The 2019 Ambon Earthquake and Preparedness For Future Disasters. International Journal of Disaster Risk Reduction, 114. https://doi.org/10.1016/j.ijdrr.2024.104961
Peng, W., Cheng, T., Wang, S., Zhao, H., Pang, L., Zhou, X., Wang, J., & Chen, Z. (2025). Basement Depth Estimation of The Red Sea Basin From Gravity Data and Drilling Data. Journal of Geophysics and Engineering, 22(4), 963–970. https://doi.org/10.1093/jge/ gxaf046
Prabowo, U.N., Raharjo, S.A., & Ariska, L. (2022). Power Spectrum Analysis of the Satellite Gravity Anomalies Data to Estimate the Thickness of Sediment Deposits in the Purwokerto-Purbalingga Groundwater Basin. http://topex.ucsd.edu/cgi-bin/get_data.cgi,
Prasetyo, I., Kadir, W. G. A., Abdurrahman, D., Dahrin, D., Ibrahim, K., & Kurniawan, A. (2025). New Insight into the Structural Model in Southern Sumatra Indonesia using Gravity and Magnetic Data: Implications for Geothermal Resources. Rudarsko Geolosko Naftni Zbornik, 40(2), 43–60. https://doi.org/10.17794/rgn.2025.2.4
Ramadhan, I., & Pohan, A. F. (2024). Pemisahan Anomali Regional dan Residual pada Metode Gravitasi Menggunakan Metode Moving Average, Upward Continuation dan Polynomial. Jurnal Fisika Unand, 13(1), 1–7. https://doi.org/10.25077/jfu.13.1.1-7.2024
Rasimeng, S., Dani, I., Syahranti, W. P., Sitompul, I. J., & Nizam, F. M. (2024). Identification of Regional Rock Depth-Residual Gravity Anomaly Based on Spectrum Analysis of Geothermal Prospect Area of Way Ratai Lampung. Gravity : Jurnal Ilmiah Penelitian Dan Pembelajaran Fisika, 10(1). https://doi.org/10.30870/gravity.v10i1.23575
Safitri, A. N., Sarwanto, S., & Harjunowibowo, D. (2023). Pengembangan Modul Pembelajaran Fisika Berbasis Kearifan Lokal Pada Materi Suhu dan Kalor. Jurnal Materi Dan Pembelajaran Fisika, 13(1), 32. https://doi.org/10.20961/jmpf.v13i1.60093
Samalehu, H., Idrus, A., & Nugroho Imam Setiawan. (2024). Geology of Tamilouw-Haya, Tehoru District, Central Maluku Regency, Maluku Province. Jurnal Geologi dan Sumberdaya Mineral-Terakreditasi KEMENRISTEKDIKTI, 23(3), 177–187. https://doi.org/10.33332/jgsm.geologi.v23.3.177-187
Sandwell, D. T., Müller, R. D., Smith, W. H. F., Garcia, E., & Francis, R. (2014). New Global Marine Gravity Model From CryoSat-2 and Jason-1 Reveals Buried Tectonic Structure. Science, 346(6205), 65–67. https://doi.org/10.1126/science.1258213
Sapiie, B., & Hadiana, M. (2013). Analogue Modeling of Oblique Convergent Strike-Slip Faulting and Application to The Seram Island, Eastern Indonesia. In Indonesian Journal on Geoscience (Vol. 1, Number 3).
Sarkowi, M. (2014). Gravity Exploration (1st ed., Vol. 1). Graha Ilmu.
Segoro, Y. A., & Margiono, R. (2025). Identification Sub-Surface Structure and Sediment Depth Estimation at the Proposed Indonesian New Capital City. Indonesian Journal of Applied Physics, 15(2), 409. https://doi.org/10.13057/ijap.v15i2.96059
Setianegara, R., Muslim, D., Ismawan, & Marjiyono (2023). Potensi Penguatan Gelombang Gempabumi oleh Sedimen Permukaan Berdasarkan Analisis Mikrotremor: Studi Kasus di Cekungan Bandung Bagian Selatan. Jurnal Geologi Dan Sumberdaya Mineral, 24(2), 107–115. https://doi.org/10.33332/jgsm.geologi.v24i2.749
Sfada, S. A. & Ali, A. (2025). Gravity Based Mapping of Sedimentary Thickness And Structural Trends in The Sokoto Basin, Northwestern Nigeria. Geological Behavior, 9(1), 01–07. https://doi.org/10.26480/gbr.01.2025.46.52
Siombone, S.H. (2022). Analisis Suhu Permukaan dan Kondisi Geomorfologi Kawasan Geotermal Tehoru Menggunakan Landsat-8 dan DEM. JGE (Jurnal Geofisika Eksplorasi), 8(3), 210–224. https://doi.org/10.23960/jge.v8i3.243
Siombone, S. H., Lestari, F. A., & Wiyono. (2024). Contextual Physics Learning Based on Geothermal Areas to Improve Scientific Literacy and Scientific Communication Skills. Jurnal Pendidikan MIPA, 25(2), 986–1011. https://doi.org/10.23960/jpmipa/v25i2.pp986-1011
Siombone, S. H., Susilo, A., & Maryanto, S. (2022). Integration of Topex Satellite Gravity and DEM SRTM Imagery for Subsurface Structure Identification at Tiris Geothermal Area, Lamongan Volcano Complex, Probolinggo, East Java. POSITRON, 12(2), 98. https://doi.org/10.26418/positron.v12i2.56880
Sismanto, Hoerunisa, A., Risdianto, D., & Rahadinata, T. (2022). The Investigation of Kadidia Geothermal Field (Indonesia) Using Gravitational Data and Power Spectrum Analysis. Jurnal Teknologi, 84(1), 149–157. https://doi.org/10.11113/jurnalteknologi.v84.17489
Toisuta, Y. M. K., Haryanto, A. D., Hutabarat, J., & Gentana, D. (2021). Pendugaan Temperatur Bawah Permukaan pada Manifestasi Panas Bumi Berdasarkan Analisis Geokimia Air Panas Daerah Kecamatan Tehoru, Kabupaten Maluku Tengah, Provinsi Maluku. Geoscience Journal, 5, 267–279. https://journals.unpad.ac.id/geoscience/article/view/35231
Tjokrosapoetro, A. S, Achdan, E. Rusmana, & H.Z. Abidin. (1993). Geology of ke Masohi Quadrangle, Maluku (Surono & T.O. Simanjuntak, Eds.; 1st ed., Vol. 1, pp. 1–17). Geological Research and Development Center, Indonesia.
USGS (2016). Landsat 8 (L8) Data Users Handbook (2.0, Vol. 8, pp. iii–76). EROS, Department of the Interior U.S. Geological Survey. https://www.usgs.gov/media/files/landsat-8-9-olitirs-collection-2-level-2-data-format-control-book
Wahyudi, E. J., Santoso, D., & Ahmad Firdaus, M. U. (2019). Gravity Survey in Pandan Mountain - East Java, Indonesia. Journal of Physics: Conference Series, 1204(1). https://doi.org/10.1088/1742-6596/1204/1/012006
Yanis, M., Ananda, R., Adhari, M. R., Paembonan, A. Y., & Ghani, A. A. (2025). Mapping The Geological Fault Zone That Triggered The Mw 6.1 Pasaman Earthquake in Indonesia on The Basis of Gravity Anomalies. Geologos, 31(2), 151–166. https://doi.org/10.14746/logos.2025.31.2.12
Zakariah, M. N. A., Roslan, N., Sulaiman, N., Lee, S. C. H., Hamzah, U., Noh, K. A. M., & Lestari, W. (2021). Gravity Analysis For Subsurface Characterization and Depth Estimation of Muda River Basin, Kedah, Peninsular Malaysia. Applied Sciences (Switzerland), 11(14). https://doi.org/10.3390/app11146363
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