A finite volume method for the solution of fluid flows coupled with the mechanical behavior of compacting porous media AIP Conf.Abstract. Seismic wave parameter plays very important role to characterize reservoir properties whereas pore parameter is one of the most important parameter of reservoir. Therefore, wave propagation phenomena in pore media is important to be studied. By referring this study, in-direct pore measurement method based on seismic wave propagation can be developed. Porosity play important role in reservoir, because the porosity can be as compartment of fluid. Many type of porosity like primary as well as secondary porosity. Carbonate rock consist many type of porosity, i.e.: inter granular porosity, moldic porosity and also fracture porosity. The complexity of pore type in carbonate rocks make the wave propagation in these rocks is more complex than sand reservoir. We have studied numerically wave propagation in carbonate rock by finite difference modeling in time-space domain. The medium of wave propagation was modeled by base on the result of pattern recognition using artificial neural network. The image of thin slice of carbonate rock is then translated into the velocity matrix. Each mineral contents including pore of thin slice image are translated to velocity since mineral has unique velocity. After matrix velocity model has been developed, the seismic wave is propagated numerically in this model. The phenomena diffraction is clearly shown while wave propagates in this complex carbonate medium. The seismic wave is modeled in various frequencies. The result shows dispersive phenomena where high frequency wave tends to propagate in matrix instead pores. In the other hand, the low frequency waves tend to propagate through pore space even though the velocity of pore is very low. Therefore, this dispersive phenomena of seismic wave propagation can be the future indirect measurement technology for predicting the existence or intensity of pore space in reservoir rock. It will be very useful for the future reservoir characterization.
The subsurface temperature has many impacts on geological phenomena such as hydrocarbon generation, geothermal energy, mineralization, and geological hazards. The Northeast Java Basin has various interesting phenomena, such as many oil fields, active faults, mud eruptions, and some active and dormant volcanoes. We measured temperature data from tens of wells along a 130 km survey line with an average spacing of 5 km. We also measured the thermal conductivity of rocks of various lithologies along the survey line to provide geothermal heat flow data. We propose integrated modeling for profiling the subsurface temperature beneath the survey line from Mt. Lawu to Mt. Muriah in the Northeast Java Basin. The modeling of subsurface temperature integrates various input data such as a thermal conductivity model, surface temperature, gradient temperature, a geological model, and geothermal heat flow. The thermal conductivity model considers the subsurface geological model. The temperature modeling uses the finite difference of Fourier’s law, with an input subsurface thermal conductivity model, geothermal heat flow, and surface temperature. The subsurface temperature profile along with survey line shows some interesting anomalies which correlate with either subsurface volcanic activity or the impact of fault activity.
Kondisi geologi di Zona Kendeng ini cukup kompleks dengan dominasi lapisan yang berumur tua dan struktur sesar naik (thrust fault) yang intensif menyebabkan sulitnya memenuhi kebutuhan air bersih dari akuifer air tanah di daerah ini. Karakter akuifer di daerah ini berupa batuan napal karbonat formasi Kerek berumur Miosen.Analisis akuifer pada penelitian ini meliputi uji resistivity rock physics, pengukuran sudut kontak, dan pengukuran resistivitas tomografi di lapangan.Pengukuran resistivity rock physics menghasilkan nilai resistivitas batuan pada keadaan kering dan pada keadaan tersaturasi air tanah. Nilai resistivitas ini menjadi referensi untuk karakterisasi citra tomografi resistivitas. Sedangkan nilai sudut kontak menunjukkan apakah air akan merambat ke atas ataukan tertekan lebih dalam. Hasil pengukuran sudut kontak yang selalu bersudut kecil memperlihatkan bahwa sistem kapilaritas di akuifer napal karbonat formasi Kerek ini mendukung untuk menjadi akuifer yang baik. Air cenderung terangkat keatas. Karakterisasi terhadap akuifer air tanah dengan metode tomografi resisitivitas berhasil mencitrakan sejumlah lokasi akuifer air tanah yang potensial meskipun dengan struktur yang relatif didominasi lapisan tegak. Permasalahannya karena akuifer napal karbonat ini dikelilingi oleh lapisan clay berumur Miosen yang impermeabel, maka recharge akuifer di daerah ini justru sangat mengandalkan akuifer dengan struktur-struktur berarah tegak.
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