DIMENSIONALITY ANALYSIS AND MODELING OF SUBSURFACE RESISTIVITY BASED ON MAGNETOTELLURIC DATA OF TINGGI RAJA GEOTHERMAL AREAS, SIMALUNGUN REGENCY

DIMENSIONALITY ANALYSIS AND MODELING OF SUBSURFACE RESISTIVITY BASED ON MAGNETOTELLURIC DATA OF TINGGI RAJA GEOTHERMAL AREAS, SIMALUNGUN REGENCY

The magnetotelurik method is a passive exploration technique that utilizes natural variations in the earth's magnetic field as a source to investigate the distribution of electrical resistivity on earth. With deep penetration, the magnetotelluric method can be used to describe the resistivit...

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Main Author: Indra Sigalingging, Pesta
Format: Theses
Language:Indonesia
Subjects:
Fisika
Online Access:https://digilib.itb.ac.id/gdl/view/46324
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Institution: Institut Teknologi Bandung
Language: Indonesia
id id-itb.:46324
spelling id-itb.:463242020-03-02T10:14:00ZDIMENSIONALITY ANALYSIS AND MODELING OF SUBSURFACE RESISTIVITY BASED ON MAGNETOTELLURIC DATA OF TINGGI RAJA GEOTHERMAL AREAS, SIMALUNGUN REGENCY Indra Sigalingging, Pesta Fisika Indonesia Theses Magnetotelluric, Geothermall, Dimensionality, Phase Tensor, Ellipticity, Bahr Parameter, Polar Diagram, Modelling. INSTITUT TEKNOLOGI BANDUNG https://digilib.itb.ac.id/gdl/view/46324 The magnetotelurik method is a passive exploration technique that utilizes natural variations in the earth's magnetic field as a source to investigate the distribution of electrical resistivity on earth. With deep penetration, the magnetotelluric method can be used to describe the resistivity distribution in geothermal systems so that the resistivity distribution characteristics can be modeled in one or two dimensions. Analysis of phase tensor and ellipticity, polar diagrams and Bahr parameters are used to determine the characteristics of the data. From the tensor phase, polar diagrams and bahr parameters can be identified that the data are 1D in the low period, 2D in the medium period and 3D in the high period. After 2D modeling, the material is conductive at a depth of about 300 m above sea level and 500 m below sea level which is identified as an area of hot water manifestation which is often called clay cap (< 5 m. ? ). The reservoir zone (10-30 m. ? ) is at a depth of about 500-100 m below sea level. Intrusive rocks zone is at a depth of more than 1000 m below sea level. From the 2D modeling slice of all measurement points, at the point of 0 m to 300 m the resistivity distribution is conductive, then the resistivity increases in the reservoir zone at a depth of 500 m below sea level and at depths greater than 500 m resistivity large enough (>100?.m) to be identified as rock which has experienced warming which is often referred to as intrusive rocks. text
institution Institut Teknologi Bandung
building Institut Teknologi Bandung Library
continent Asia
country Indonesia
Indonesia
content_provider Institut Teknologi Bandung
collection Digital ITB
language Indonesia
topic Fisika
spellingShingle Fisika
Indra Sigalingging, Pesta
DIMENSIONALITY ANALYSIS AND MODELING OF SUBSURFACE RESISTIVITY BASED ON MAGNETOTELLURIC DATA OF TINGGI RAJA GEOTHERMAL AREAS, SIMALUNGUN REGENCY
description The magnetotelurik method is a passive exploration technique that utilizes natural variations in the earth's magnetic field as a source to investigate the distribution of electrical resistivity on earth. With deep penetration, the magnetotelluric method can be used to describe the resistivity distribution in geothermal systems so that the resistivity distribution characteristics can be modeled in one or two dimensions. Analysis of phase tensor and ellipticity, polar diagrams and Bahr parameters are used to determine the characteristics of the data. From the tensor phase, polar diagrams and bahr parameters can be identified that the data are 1D in the low period, 2D in the medium period and 3D in the high period. After 2D modeling, the material is conductive at a depth of about 300 m above sea level and 500 m below sea level which is identified as an area of hot water manifestation which is often called clay cap (< 5 m. ? ). The reservoir zone (10-30 m. ? ) is at a depth of about 500-100 m below sea level. Intrusive rocks zone is at a depth of more than 1000 m below sea level. From the 2D modeling slice of all measurement points, at the point of 0 m to 300 m the resistivity distribution is conductive, then the resistivity increases in the reservoir zone at a depth of 500 m below sea level and at depths greater than 500 m resistivity large enough (>100?.m) to be identified as rock which has experienced warming which is often referred to as intrusive rocks.
format Theses
author Indra Sigalingging, Pesta
author_facet Indra Sigalingging, Pesta
author_sort Indra Sigalingging, Pesta
title DIMENSIONALITY ANALYSIS AND MODELING OF SUBSURFACE RESISTIVITY BASED ON MAGNETOTELLURIC DATA OF TINGGI RAJA GEOTHERMAL AREAS, SIMALUNGUN REGENCY
title_short DIMENSIONALITY ANALYSIS AND MODELING OF SUBSURFACE RESISTIVITY BASED ON MAGNETOTELLURIC DATA OF TINGGI RAJA GEOTHERMAL AREAS, SIMALUNGUN REGENCY
title_full DIMENSIONALITY ANALYSIS AND MODELING OF SUBSURFACE RESISTIVITY BASED ON MAGNETOTELLURIC DATA OF TINGGI RAJA GEOTHERMAL AREAS, SIMALUNGUN REGENCY
title_fullStr DIMENSIONALITY ANALYSIS AND MODELING OF SUBSURFACE RESISTIVITY BASED ON MAGNETOTELLURIC DATA OF TINGGI RAJA GEOTHERMAL AREAS, SIMALUNGUN REGENCY
title_full_unstemmed DIMENSIONALITY ANALYSIS AND MODELING OF SUBSURFACE RESISTIVITY BASED ON MAGNETOTELLURIC DATA OF TINGGI RAJA GEOTHERMAL AREAS, SIMALUNGUN REGENCY
title_sort dimensionality analysis and modeling of subsurface resistivity based on magnetotelluric data of tinggi raja geothermal areas, simalungun regency
url https://digilib.itb.ac.id/gdl/view/46324
_version_ 1822927324239101952

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