MAGNETIC BASEMENT RELIEF ESTIMATION OF SUMANI AND SIANOK SEGMENT IN THE GREAT SUMATRAN FAULT
The magnetic method is one of the geophysical methods used to delineate structures beneath the Earth's surface, one of which is the magnetic basement relief (MBR). Basement structure modeling has been developed due to its usefulness in the exploration of hydrocarbons and minerals. This struc...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/73678 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | The magnetic method is one of the geophysical methods used to delineate structures
beneath the Earth's surface, one of which is the magnetic basement relief (MBR).
Basement structure modeling has been developed due to its usefulness in the
exploration of hydrocarbons and minerals. This structural modeling is usually carried
out in sedimentary basin areas to detect the boundaries between the sediment layers
and the magnetic basement to estimate the hydrocarbon potential in the studied area.
The Sumani segment is a volcanic area with complex geological conditions dominated
by many rock intrusive bodies that is part of the Sumatran Fault. MBR modeling in this
area tends to be difficult because the susceptibility value contrasts of the constituent
rocks are not high. Being part of the Ring of Fire complex, Indonesia hosts many
volcanic areas. If MBR modeling can be successfully carried out in the Sumani Segment
area, this will be the first step in implementing this method in Indonesia. Initially, the
MBR modeling process was difficult to carry out. Several technologies, methods, and
programs have been studied to ease the process of MBR modeling. Among those
methods, there is the MagB_Inv program that was developed based on the iterative
inversion method, and the Euler deconvolution method has also been used by several
researchers to estimate the model of MBR. Both of those methods will be used in this
research. The Euler deconvolution procedure was carried out three times using
structural index (SI) values of 0, 1, and 2. Then, the results obtained from the modeling
were analyzed based on the difference in the average depth and the relief pattern
between the modeling results and the reference model obtained from previous studies.
Based on the analysis of the results of all the methods used, the MagB_Inv program
has limitations for modeling research areas with complex geological structures, so it
is not suitable for modeling this research area. The limitation occurred due to the
magnetization contrast parameters and average depth as the initial parameters for
MagB_Inv modeling. The magnetization contrast parameter allows modeling to be
carried out by assuming the study area is divided into two main layers consisting of the
MBR layer and other rock layers above it, which causes lateral variations in the study
area caused by the rocks not being imaged properly. For the average depth parameter,
because only one value is used as the basis for the MBR modeling for the entire study5
area regardless of its size and geological complexity, the complex geological
conditions cannot be properly represented. It happens because, in areas with complex
geology, the contrast in basement depth values between one zone and another can be
very different, so using one average depth value as the initial model for all regions is
not appropriate. As for the Euler deconvolution method, of the three structural indices
used, the most optimal results are obtained when using a value of 1. Of all the methods
used in this study, the most suitable method to be applied to the Sumani Segment area
is the Euler deconvolution method with SI = 1. Furthermore, for additional analysis,
modeling was also carried out in the Sianok Segment area using MagB_Inv. The Sianok
Segment area was chosen due to the presence of a thick tuff layer on the surface, which
can represent a sedimentary basin area. The modeling results show conformity with
the reference, proving that the MagB_Inv program can be utilized to model the MBR
in the volcanic region if it is composed of thick tuff layers. |
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