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"Seperti hal nya lapangan geotermal yang sudah diekstraksi lebih dari 25 tahun, Salak juga mengalami penurunan produksi akibat cooling atau penurunan suhu pada reservoir. Analisis 3G, yaitu Geofisika, Geokimia, dan Geologi yang dilakukan seringkali tidak sesuai dengan data sumur, karena kesalahan mendasar dari interpretasi zona resistivitas rendah, barrier sesar atau marjin reservoir terutama pada reservoir di bawah sumur produksi dan injeksi lapangan Salak. Semua data yang dianalisis adalah data yang diperoleh pada waktu sumur awal diproduksi. Analisis penyebaran zona resisitivitas dengan metode seleksi dan re-prosessing yang tepat menjadi hal dasar dari penentuan batas area prospek dan zona uplow dan outflow. Sebaran dan kedalaman zona konduktif mendeskripsikan penyebaran mineral alterasi, kontak litologi, barrier patahan, batas TOR dan BOC (updome shape), perubahan suhu karena perbedaan kontras dari jalur permeabilitas dan arah aliran fluida. Pola ketebalan resistivitas yang relatif sama di atas reservoir atau batas low resistivity anomaly mungkin menghasilkan kesalahan interpretasi dari noise yang perlu dikoreksi. Penelitian ini diharapkan dapat memberikan informasi model konseptual yang lebih konsisten, representatif dan terintegrasi serta menunjukkan kesesuaian dengan data pendukung lainnya, sehingga dapat mengidentifikasi masalah yang dihadapi, dan selanjutnya memberikan hipotesis untuk menjaga keberlangsungan performa reservoir.

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Like most geothermal field which has been extracted for more than 25 years, Salak has been also experienced the production decline, which is quite likely caused by change of well pressure and cooling in reservoir. The existing 3G analysis was frequently contradicted with well data, especially caused by misinterpretation of noisy and low deep resistivity. Furthermore, all corrected 3D inversion MT data is compared with well data, geology , and geochemical data, to produce updated and integrated conceptual model, which can be expexted to re-evaluate analysis of changes in the distribution of resistive zones at initial reservoir conditions that give indication of distribution of alteration minerals, TOR and BOC (updome shape) boundary, lithology contacts, variation of pressure and temperature, and give identification of permeability zone contrasting and fluid pathway, fault orientation corresponds to good aggrement of interpetation of low resistivity zone and well data. The powerfull and developed 3D MT Inversion and observation of anomalous resistivity feature interpreted as clay alteration, fault barrier, upflow and or the expansion of neutral spring water in ouflow zone near Awi 20 and 15. This anomaly is strongly correlated to the temperature changes in hydrothermal mineral. This variation shows the deep and shallow up-dome shaped of geothermal system below Awi 9, 10 and 14, confirmed by Parabakti and Cibeureum fumarol analysis, thin clay cap, fault intersection map and especially high temperature in well data. To test this hypothesis, writer recast all supporting data with revised resistivity model. This research is expected to provide information on a representative conceptual model and accurate analysis to the current problems respectively, hence improved approachs can be taken to implement further recommendation on how to hypothesize a strategic solution to maintain reservoir performance. "

"Lapangan Geotermal Salak merupakan lapangan geotermal terbesar di Indonesia dengan kapasitas terpasang sebesar 377 MW. Dari awal beroperasinya pada Februari 1994 sampai dengan Desember 2014 lapangan ini telah memproduksi 421.759.106,78 Ton uap. Dengan produksi sebesar itu, diperlukan manajemen reservoar yang baik untuk menjaga keberlangsungan produksi jangka panjang. Manajemen reservoar sangat penting dalam upaya mengatasi masalah yang terjadi akibat kegiatan produksi dan reinjeksi, oleh karena itu strategi reinjeksi sebaiknya memperhatikan karakteristik reservoar lapangan geotermal. Penelitian ini menggunakan metode geofisika yaitu 3D MT, Microearthquake dan Microgravity dengan dukungan data sumur dan data produksi serta reinjeksi untuk memprediksi kondisi reservoar sebagai upaya mengantisipasi terjadinya penurunan tekanan reservoar yang berpotensi menurunkan produktifitas sumur produksi. Hasil penelitian ini menyimpulkan bahwa strategi reinjeksi di Awi 9 memegang peranan penting sebagai heat and pressure support di sumur ? sumur produksi. Namun, terdapat indikasi kompaksi pada reservoar sejalan dengan peningkatan kapasitas produksi, hal ini diperkuat dengan terjadinya penurunan permukaan tanah dan peningkatan kejadian gempa mikro pada daerah resevoar dangkal, terjadi penurunan medan gravitasi pada reservoar produksi yang diidentifikasi berhubungan dengan penurunan tekanan reservoar. Hasil ini digunakan sebagai dasar usulan untuk mempertahankan eksistensi sumur - sumur reinjeksi di Awi 9 dan penempatan sumur reinjeksi brine di zona reservoar produksi.

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Salak Geothermal Field is the biggest geothermal field in Indonesia with 377 MW installed capacity. From its commersial operation in February to December 2015, this field has produced 421.759.106,78 Tonnes steam. With these huge production, good reservoir management are necessary to sustain long term production. Reservoir management becomes very important to overcome the problems caused by production and reinjection. Therefore, reinjection strategy should be implemented by considering reservoar characteristic in geothermal field.

This study are using geophysical methods, there are : 3D MT, Microearthquake and Microgravity combined to geological well data support, production and reinjection data to predict reservoir condition as an attempt to anticipate decreasing of reservoir pressure which potentially reduce production.

This study conclude that reinjection strategy in Awi 9 took important part as heat and pressure support to production wells. However, there are some indication of creep compaction in reservoir in line with production capacity escalation, this was supported by land subsidence and increasing of microearthquake event in the shallow part of reservoir, decreasing of gravitational field in production reservoir associated with reservoir pressure drops, this results are used as the basis for the proposals to maintain the existance of reinjection wells in Awi 9 and brine reinjection wells placement in the production reservoir zone."

"Untuk menentukan zona prospek diperlukan beberapa kriteria yaitu struktur yang berasosiasi dengan permeabilitas tinggi, temperatur tinggi dan zona upflow. Berdasarkan peta lineament density serta metode FFD menunjukkan zona yang memiliki densitas tinggi berasosiasi dengan zona depresi yang merupakan struktur utama pada lapangan panasbumi ldquo;Q rdquo; dan munculnya beberapa manifestasi berupa fumarol, dan mata air panas APWO, APWK, APLM dan APBK. Dari diagram ternary Cl - SO4 - HCO3 menunjukkan APWO memiliki tipe steam heated water, APWK memiliki tipe bicarbonate water sedangkan APBK dan APLM memiliki tipe chloride water. Berdasarkan tipe fluida tersebut maka dapat diklasifikasikan bahwa lapangan panasbumi ldquo;Q rdquo; merupakan sistem hidrotermal. Penentuan estimasi temperatur reservoir menggunakan geothermometer silika dan geothermometer gas yang masing - masing berkisar antara 141 C - 212 C dan 250 C. Sehingga manifestasi APWO, FWO-1 dan FWO-2 menunjukkan berada pada zona upflow dan APWK, APBK, APLM berada pada zona outflow. Hasil dari inversi 3D MT memperlihatkan sebaran resistivitas rendah < 10 ohm-m memiliki ketebalan 1000 m sampai 1500 m yang diduga sebagai clay cap, sebaran zona resistivitas tinggi > 100 ohm-m terlihat berbentuk updome pada kedalaman -500 sampai -4000 m yang diduga sebagai heat source. Dari hasil proses upward continuation dan reduce to pole, nilai magnetik yang berkisar -250 nT sampai -350 nT berada di bawah manifestasi FWO-01, FWO-02, APWO dan daerah dimana alterasi tersingkap. Sehingga dapat disimpulkan bahwa area yang memiliki densitas tinggi berkorelasi dengan sebaran resistivitas yang bernilai 10 ohm-m dan daerah yang memiliki nilai anomali magnetik rendah -250 nT sampai -200 nT dimana mengindikasikan zona reservoir berasosiasi dengan batas bawah clay cap atau BOC.

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To determine the prospek area in geothermal field, must have the structure associated with high permeability, high temperature and upflow zone. Based on the map of lineament density and the FFD method shows a high density zone associated with the depression zone which is the main structure of the filed Q and the emergence of several manifestations of fumaroles and hot springs APWO, APWK, APLM and APBK. From the ternary diagram Cl SO4 HCO3 shows that APWO has steam heated water type, APWK has bicarbonate water type while APBK and APLM are chloride water type. Based on the obtained geochemical manifestations the geothermal system is a hydrothermal system. Prediction of reservoir temperature using silica geothermometer and gas geothermometer each ranging between 141 C 212 C and 250 C. So the manifestations of APWO, FWO 1 and FWO 2 indicate that they are in the upflow zone and APWK, APBK, APLM are in outflow zone.

The result of 3D MT inversion shows low resistivity 100 ohm m appears to be an updome at depths of 500 to 4000 m suspected as heat source. From the upward continuation and reduce to pole results, magnetic values ranging from 250 nT to 350 nT are under the manifestations of FWO 01, FWO 02, APWO and the areas where alteration is exposed. It can be concluded that areas with high densities are correlated with 10 ohm m resistivity distributions and regions having low magnetic anomaly values 250 nT to 200 nT which indicate the reservoir zone associated with the lower limit of clay cap or BOC."

"Pemanfaatan potensi panas bumi di Gunung Galunggung yang merupakan salah satu gunungapi aktif di Indonesia belum dilakukan hingga saat ini. Studi mengenai sistem panas bumi daerah terkait belum banyak dilakukan. Studi pada penelitian ini dilakukan untuk memperjelas pendefinisian sistem pada model konseptual sebelumnya. Studi dilakukan untuk mengetahui keadaan sistem panas bumi daerah penelitian menggunakan data utama geologi dan geokimia. Metode yang digunakan antara lain metode penginderaan jauh, pemetaan geologi lapangan, petrografi, serta analisis geokimia dan isotop air yang diintegrasi dengan data gaya berat dan magnetotelluric literatur. Hasil studi menunjukkan keberadaan sumber panas yang berkaitan dengan vulkanisme aktif Gunung Galunggung. Batuan penudung terduga berada di utara hingga selatan daerah penelitian dengan reservoir yang terbentang di bawahnya. Pendugaan suhu reservoir memiliki kisaran antara 143-152°C menggunakan geotermometer Na-K-Ca. Fluida berasal dari air meteorik dan reservoir yang sama. Fluida panas bumi akan masuk melaui daerah imbuhan di utara, lalu terpanaskan oleh sumber panas, mengalir ke atas sehingga air kondensat termanifestasi, dan mengalir ke selatan hingga air klorida terencerkan termanifestasi. Permeabilitas dikontrol oleh struktur depresi di utara dan sesar normal dari komplek deformasi kuat di selatan. Sistem panas bumi daerah penelitian dikategorikan menjadi dinamis konvektif high-enthalphy liquid-dominated high-relief yang berasosiasi dengan vulkanisme Kuarter Gunung Galunggung.

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The utilization of geothermal potential on Mount Galunggung, one of the active volcanoes in Indonesia, has not been carried out yet. There have not been many studies on the geothermal system in the related areas. The study in this research was conducted to further clarify the how the system works in the previous conceptual model. The study was conducted to determine the state of the geothermal system in the research area mainly using the geological and geochemical data. The methods used include remote sensing methods, field geological mapping, petrography, and geochemical and water isotope analysis integrated with gravity and magnetotelluric literature data. The results of the study indicate the presence of a heat source related to the active volcanism of Mount Galunggung. The expected cap rocks are in the north to south of the study area with the reservoir extending beneath it. The reservoir temperature estimation has a range between 143-152°C using Na-K-Ca geothermometer. The fluids originated from meteoric water and the same reservoir. Geothermal fluid will enter through the recharge area in the north, heated by a heat source, flow upwards so the steam-condensate water is manifested, and flows south until dilute chloride water is manifested. Permeability is controlled by the depression structure in the north and the normal fault of the strong deformation complex in the south. The geothermal system in the study area is categorized as a high-enthalphy liquid-dominated high-relief convective dynamic associated with the Galunggung Quaternary volcanism."

"[Kegiatan eksplorasi geothermal bertujuan mengetahui sistem geothermal daerah penyelidikan yang meliputi model dan batas prospek, karakteristik dan potensial reservoir dan hidrogeologi, untuk penentuan target pemboran, dilanjutkan dengan pemboran eksplorasi.Hasil inversi 3-dimensi data MT akan menyajikan distribusi struktur resistivitas bawah permukaan.Pemboran eksplorasi geothermal bertujuan untuk membuktikan adanya sumber daya geothermal dan menguji model sistem geothermal yang telah dibuat. Kriteria target pemboranadalah area yang memiliki temperature dan permeabilitas yang tinggi. Pada waktu pemboran sumur panas bumi ditembusnya zona bertemperatur tinggi yang disertai atau diikuti dengan terjadinya loss of circulation sangat diharapkan (permeabilitas tinggi), karena merupakan suatu indikasi telah ditembusnya rekahan-rekahan yang diharapkan merupakan zona produksi (feed zone).Untuk menguji model sistem yang dibuat dilakukan korelasi antara data hasil pemboran dengan inverse 3D data MT, khususnya nilai resistivity lapisandengan data temperatur, kandungan mineral alterasi, geokimia dari data pemboran.Dari hubunganantar parameter akan terlihat karakteristik sistem geothermal di daerah penyelidikan, yang memperlihatkan zona prospek yang berhubungan dengan temperature dan permeabilitas yang tinggi. Dari hasil evaluasi akan dilakukan rekonstruksi system geothermal daerah penyelidikan, yang lebih mendekati kondisi bawah permukaan dan dapat dipergunakan untuk membuat rekomendasi pemboran selanjutnya dan arah pengembangan di masa yang akan datang;Geothermal exploration activities aimed at knowing the geothermal system that includes model and boundary the prospects, potential and reservoir characteristics and also hydrological system. By using 3D inversion of MT data, subsurface resistivity distribution structure can be obtained and with the addition of other geosciences data, LumutBalai geothermal system can be constructed. Futhermore, drilling targets zone can be identified from geothermal system which then followed by exploration drilling .Geothermal exploration drilling is carried out to verify the existence of geothermal resources and test the geothermal systems which previously has been made. Drilling target criteria is the area which consist of high temperature and permeability. During geothermal drilling, it is expected that high temperature zone shall be encountered. It will be followed by loss circulation zone which indicates that fractures have already been penetrated and confirm that feed zone has been discovered.In order to test constructed model, correlation between drilling data and 3D MT inverse is carried out, particularly values of resistivity layer with temperature data, alteration mineralcomposition, and geochemical data derived from drilling.Parameter correlation will explain geothermal system characteristics in study area which delineates prospect zones and its association with high temperature and permeability. The evaluation results of this study will reconstruction geothermal system the investigation area, which can be used to develop a recommendation of subsequent drilling and further development direction;Geothermal exploration activities aimed at knowing the geothermal system that includes model and boundary the prospects, potential and reservoir characteristics and also hydrological system. By using 3D inversion of MT data, subsurface resistivity distribution structure can be obtained and with the addition of other geosciences data, LumutBalai geothermal system can be constructed. Futhermore, drilling targets zone can be identified from geothermal system which then followed by exploration drilling .Geothermal exploration drilling is carried out to verify the existence of geothermal resources and test the geothermal systems which previously has been made. Drilling target criteria is the area which consist of high temperature and permeability. During geothermal drilling, it is expected that high temperature zone shall be encountered. It will be followed by loss circulation zone which indicates that fractures have already been penetrated and confirm that feed zone has been discovered.In order to test constructed model, correlation between drilling data and 3D MT inverse is carried out, particularly values of resistivity layer with temperature data, alteration mineralcomposition, and geochemical data derived from drilling.Parameter correlation will explain geothermal system characteristics in study area which delineates prospect zones and its association with high temperature and permeability. The evaluation results of this study will reconstruction geothermal system the investigation area, which can be used to develop a recommendation of subsequent drilling and further development direction, Geothermal exploration activities aimed at knowing the geothermal system that includes model and boundary the prospects, potential and reservoir characteristics and also hydrological system. By using 3D inversion of MT data, subsurface resistivity distribution structure can be obtained and with the addition of other geosciences data, LumutBalai geothermal system can be constructed. Futhermore, drilling targets zone can be identified from geothermal system which then followed by exploration drilling .Geothermal exploration drilling is carried out to verify the existence of geothermal resources and test the geothermal systems which previously has been made. Drilling target criteria is the area which consist of high temperature and permeability. During geothermal drilling, it is expected that high temperature zone shall be encountered. It will be followed by loss circulation zone which indicates that fractures have already been penetrated and confirm that feed zone has been discovered.In order to test constructed model, correlation between drilling data and 3D MT inverse is carried out, particularly values of resistivity layer with temperature data, alteration mineralcomposition, and geochemical data derived from drilling.Parameter correlation will explain geothermal system characteristics in study area which delineates prospect zones and its association with high temperature and permeability. The evaluation results of this study will reconstruction geothermal system the investigation area, which can be used to develop a recommendation of subsequent drilling and further development direction]"

"Daerah penelitian terletak di Muara Laboh, kabupaten Solok Selatan Sumatera Barat dan secara tektonik terdapat pada ujung segmen Suliti yang berasosiasi dengan sesar geser menganan (dextral strike slip fault) Sesar Sumatera. Daerah penelitian merupakan sistem panasbumi dengan dua phase yaitu sistem dominasi uap yang memiliki lapisan reservoir dominasi uap setebal ±400 m di atas zona dominasi air.Zona Altereasi di daerah penelitian dibagi menjadi dua yaitu zona alterasi argillic yang di tandai dengan kehadiran mineral clay (smectite) betemperatur rendah dan lapisan ini digunakan sebagai lapisan penudung (cap rock) dan kedua adalah zona alterasi prophylitic yang di tandai dengan kehadiran mineral sekunder bertemperatur tinggi seperti epidote, kuarsa, calcite, chlorite dan lapisan ini digunakan sebagai zona resrvoir (zona produksi). Permeabilitas zona produktif di sumur-sumur produksi tidak hanya dikontrol oleh jenis litologi dan unit batuan tapi juga dikontrol oleh bidang-bidang patahan dan zona rekahan di sekitarnya. Puncak reservoir rata-rata berada pada elevasi 1000-1100 mdpl. Sedangkan brine level teramati pada elevasi 400-600 mdpl. Temperatur dan tekanan yang lebih rendah, serta kandungan gas yang lebih tinggi bukan disebabkan oleh kompartementasi reservoir, tapi lebih disebabkan oleh lokasi sumur yang berada di dekat margin reservoir. Sumur re-injeksi di margin reservoir dibutuhkan untuk mengatasi penurunan tekanan reservoir yang cepat. Salah satu alternatif lokasi sumur injeksi adalah di bagian timur dan utara dari sumur produksi, dimana sumur injeksi harus dibor hingga menembus reservoir dominasi air. Dari hasil tahapan eksplorasi daerah penelitian yang baik untuk di kembangkan adalah dibagian selatan.

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The study area is located in Muara Laboh, South Solok regency of West Sumatra and is tectonically located on the tip of Suliti segment associated with the fault shear are heading (dextral strike-slip fault) Fault Sumatra. The study area is a geothermal system with a two-phase vapor-dominated system that has a layer of thick steam reservoir dominance ± 400 m above zone air.Zona Altereasi dominance in the study area was divided into two argillic alteration zones are marked by the presence of clay minerals (smectite) betemperatur low and this layer is used as the covering layer (cap rock) and the second is prophylitic alteration zones are marked by the presence of secondary high-temperature minerals such as epidote, quartz, calcite, chlorite and this layer is used as resrvoir zone (zone of production). Permeability zone in the prolific production wells is not only controlled by the type of lithology and rock units but also controlled by fields of faults and fracture zones in the vicinity. Peak average reservoir located at an elevation of 1000-1100 meters above sea level. While the brine level observed at the elevation of 400-600 meters above sea level. Temperature and lower pressure, as well as higher gas content is not caused by kompartementasi reservoir, but more due to the location of the wells near the reservoir margins. Reinjection wells in the reservoir margin needed to overcome the reservoir pressure drops rapidly. One alternative is the location of injection wells in the east and north of the production wells, where injection wells should be drilled to penetrate the dominance of the water reservoir. From the results of the exploration stage is a good research area to be developed is in the south."

"Parakasak adalah salah satu gunung berapi kuaterner yang sebagian besar tersusun oleh lava andesitik dan piroklastik. Potensi sistem panas bumi terlihat oleh manifestasi sumber air panas di Batukuwung sebagai objek wisata lokal. Penelitian ini bertujuan untuk mengetahui sistem panas bumi di sana dan membuat model konseptual melalui pemahaman kita tentang karakteristik mereka. Metode untuk mencapai ini dapat dilakukan dengan mengambil dan menganalisis sampel geologi, analisis petrografi sebagai data primer, analisis geokimia dan geofisika sebagai data sekunder. Berdasarkan analisis di atas, Mt. Parakasak adalah stratovolcano relief tinggi dengan dua sesar tektonik yaitu sesar Batukuwung dan sesar Wangun. Ia juga memiliki struktur runtuh di pusat gunung sebagai hasil dari letusannya di masa lalu. Karakteristik sistem panas bumi di daerah ini didominasi cairan, air meteorik sebagai sumber, dan memiliki suhu sedang (175˚C-230 ˚C). Sumber panas berasal dari ruang magma dan reservoir adalah lava andesit piroklastik dan fraktur.

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Mt. Parakasak is a quaternary volcano composed mostly of andesitic and pyroclastic lava. Potential geothermal systems are seen by the manifestation of hot springs in Batukuwung as a local tourist attraction. This research aims to find out the geothermal system there and create a conceptual model through our understanding of their characteristics. Methods to achieve this can be done by taking and analyzing geological samples, petrographic analysis as primary data, geochemical analysis and geophysics as secondary data.

Based on the above analysis, Mt. Parakasak is a high relief stratovolcano with two tectonic faults, the Batukuwung fault and the Wangun fault. It also has a collapsed structure at the center of the mountain as a result of its eruption in the past. The characteristics of geothermal systems in this area are dominated by liquids, meteoric water as a source, and has a moderate temperature (175˚C-230 ˚C). The heat source comes from the magma chamber and the reservoir is pyroclastic andesite lava and fracture."

"Eksplorasi panas bumi merupakan tahapan yang sangat penting pada kegiatan pengusahaan panas bumi karena memiliki tingkat resiko kegagalan pemboran yang sangat tinggi serta biaya yang dikeluarkan cukup besar. Oleh karena itu, diperlukan interpretasi terpadu berdasarkan data geosains untuk mendelineasi prospek sistem geothermal Gn. Lawu sehingga penentuan lokasi pemboran mempunyai tingkat kepastian yang lebih tinggi. Dalam mendelineasi sistem geothermal sangat ditentukan dengan sebaran batuan resistivitas rendah yang mengindikasikan adanya lapisan penudung (caprock) yang didominasi oleh material lempung. Selain itu, target utama dari eksplorasi panas bumi adalah temperatur dan permeabilitas batuan yang tinggi. Distribusi sebaran temperatur bawah permukaan dapat diperkirakan melalui data manifestasi pada lokasi penelitian. Sedangkan permeabilitas tinggi berasosiasi dengan zona patahan dimana fluida dapat mengalir ke permukaan. Magnetotelluric (MT) merupakan metode geofisika pasif yang melibatkan pengukuran fluktuasi medan listrik dan magnet alam sebagai sarana untuk menentukan resistivitas batuan di bawah permukaan bumi dimana pemodelan data MT dapat dilakukan menggunakan inversi 3D. Untuk memahami lebih lanjut mengenai pemodelan MT tersebut, maka penelitian ini difokuskan pada inversi 3D dengan MT3Dinv-X yang kemudian diintegrasikan dengan data dukung gravitasi, geologi dan geokimia untuk mendelineasi sistem geothermal Gn. Lawu. Hasil akhir penelitian ini adalah memberikan rekomendasi pola sebaran resistivitas batuan serta membuat model konseptual untuk menentukan area target pemboran pada daerah penelitian.

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Geothermal exploration is crucial step in geothermal business because it has uncertainty drilling result and high cost. Therefore, an integrated interpretation based on geosciences data is needed to delineate the prospect of Gn. Lawu geothermal system so the location of drilling could be more convince. The distribution of low resistivity rocks that indicating the presence of a caprock which is dominated by the material of clay. Moreover, the main target of geothermal exploration is the high temperature and permeability of rocks. The distribution of subsurface temperature can be estimated through the manifestation data on site. High permeability is associated with a fault zone where fluid can flow to the surface. Magnetotelluric (MT) is a passive geophysical method that involves measuring the fluctuations of electric and natural magnetic fields as a means of determining the resistivity of rocks beneath the Earth's surface where MT data modeling can be performed using 3D inversion. To understand more about the MT modeling, this research is focused on 3D inversion with MT3Dinv-X which is then integrated with gravity, geological and geochemical support data to delineate Gn. Lawu geothermal system. The final result of this research is to recommend the pattern of distribution of rock resistivity as well as to create conceptual model to determine drilling target area in research area."

"Wilayah geothermal Tulehu ditandai oleh kemunculan manifestasi permukaan. Tidak ada manifestasi yang mengindikasikan zona upflow. Survei geosains telah dilakukan dan diikuti oleh pengeboran 4 sumur eksplorasi. Namun, penggambaran zona upflow suhu tinggi yang terkait dengan sumber panas masih sulit. Hal ini karena area survei geosains yang dilakukan belum mencakup keseluruhan sistem geotermal (daerah upflow dan outflow). Dugaan keberadaan sumber panas kemungkinan menuju G. Eriwakang seperti yang ditunjukkan oleh distribusi temperatur dari data sumur. Berdasarkan studi data geosains yang tersedia, diintegrasikan dengan data sumur yang ada, maka dibuat model konseptual yang mencakup kemungkinan keberadaan sumber panas (zona upflow) di sekitar G. Eriwakang dan kemunculan manifestasi permukaan sebagai zona outflow. Untuk menyelidiki kemungkinan lokasi sumber panas sistem geotermal Tulehu, maka simulasi reservoir dilakukan berdasarkan model konseptual yang telah dibuat dengan menggunakan simulator TOUGH2/iTOUGH2. Hasil simulasi setelah mencapai kondisi natural state menunjukkan bahwa sumber panas dimungkinkan berada di bawah G. Eriwakang. Hal ini ditunjukkan dengan kesesuaian kurva temperatur vs kedalaman antara hasil simulasi dengan data sumur. Untuk mengkonfirmasi hasil penelitian ini, maka direkomendasikan untuk dilakukan survei geosains lebih lanjut.

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Tulehu geothermal area is characterised by surface manifestations. Fumarole and other steam-type manifestations are absent. Geoscientific surveys covering thermal manifestations area have been conducted followed by exploration drillings. However, delineation of high temperature up-flow zone associated with heat source is still challenging, even drilling data from 4 wells could not answer the question yet. Possible existence of the heat source is likely toward Mt Eriwakang as indicated by temperature distribution from wells. Based on the geoscientitic data study, integrated with the existing well data, a conceptual model was developed that includes the possibility of the existence of a heat source (upflow zone) around G. Eriwakang and the appearance of surface manifestations as the outflow zones. To investigate the possible location of the heat source of the Tulehu geothermal system, reservoir simulations using TOUGH2/iTOUGH2 simulator were carried out based on the conceptual model that has been made. Simulation results, after achieving natural state conditions, indicate that the heat source is possibly located under Mt. Eriwakang. This is indicated by the suitability of the temperature vs. depth curve between the simulation results and the well data. Furthermore, to confirm the existence of the heat source, further geoscientific surveys are recommended to be carried out in this area."

"Lapangan geotermal X berada di area gunung A yangmana berdasarkan data geologi ditemukan adanya manifestasi berupa hot spring dan fumarole. Pengukuran MT dilakukan untuk mengetahui persebaran resistivity batuan di bawah permukaan. Pengolahan data MT dilakukan dari analisis time series dan filtering noise kemudian dilakukan Transformasi Fourier dan Robust Processing. Setelah itu baru dilakukan crosspower untuk menyeleksi data sehingga output dari proses ini berupa kurva MT. Setelah didapatkan kurva MT dilakukan koreksi statik dikarenakan kurva TE dan TM terjadi shifting. Untuk proses akhirnya baru dilakukan inversi 2D dan inversi 3D. setelah itu dilakukan perbandingan antara 2D dan 3D. Wilayah interest lapangan X berada di lintasan AA dan lintasan AB. Berdasarkan analisis 3D diidentifikasi bahwa zona alterasi menipis di wilayah upflow dan menebal ke arah outflow yangmana sesuai dengan teori. Wilayah upflow dapat diketahui dengan melihat manifestasi berupa fumarole.

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The geothermal field X is located in the area of Mount A which based on geological data found the presence of hot spring and fumarole manifestations. MT measurements were carried out to determine the distribution of rock resistivity in the subsurface. MT data processing is starts from time series analysis and noise filtering then Fourier Transform and Robust Processing are performed. After that, crosspower is done to select data so that the output of this process is an MT curve. After got the MT curve then a static correction is done because the TE and TM curves are shifting. For the final process are 2D inversion and 3D inversion. After that make a comparison between 2D and 3D. The area of interest in field X is on the line AA and line AB. Based on the 3D analysis, it was identified that alteration zones thinned in the upflow region and thickened towards the outflow which is make sense with the theory."