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가스 하이드레이트 부존층의 구조파악을 위한 탄성파 AVO 분석 AVO모델링, AVO역산
김건득(Kim, Gun-Duk),정부흥(Chung, Bu-Heung) 한국신재생에너지학회 2005 한국신재생에너지학회 학술대회논문집 Vol.2005 No.06
The gas hydrate exploration using seismic reflection data, the detection of BSR(Bottom Simulating Reflector) on the seismic section is the most important work flow because the BSR have been interpreted as being formed at the base of a gas hydrate zone. Usually, BSR has some dominant qualitative characteristics on seismic section i.e. Wavelet phase reversal compare to sea bottom signal, Parallel layer with sea bottom, Strong amplitude, Masking phenomenon above the BSR, Cross bedding with other geological layer. Even though a BSR can be selected on seismic section with these guidance, it is not enough to conform as being true BSR. Some other available methods for verifying the BSR with reliable analysis quantitatively i.e. Interval velocity analysis, AVO(Amplitude Variation with Offset)analysis etc. Usually, AVO analysis can be divided by three main parts. The first part is AVO analysis, the second is AVO modeling and the last is AVO inversion. AVO analysis is unique method for detecting the free gas zone on seismic section directly. Therefore it can be a kind of useful analysis method for discriminating true BSR, which might arise from an Possion ratio contrast between high velocity layer, partially hydrated sediment and low velocity layer, water saturated gas sediment. During the AVO interpretation, as the AVO response can be changed depend upon the water saturation ratio, it is confused to discriminate the AVO response of gas layer from dry layer. In that case, the AVO modeling is necessary to generate synthetic seismogram comparing with real data. It can be available to make conclusions from correspondence or lack of correspondence between the two seismograms. AVO inversion process is the method for driving a geological model by iterative operation that the result ing synthetic seismogram matches to real data seismogram wi thin some tolerance level. AVO inversion is a topic of current research and for now there is no general consensus on how the process should be done or even whether is valid for standard seismic data. Unfortunately, there are no well log data acquired from gas hydrate exploration area in Korea. Instead of that data, well log data and seismic data acquired from gas sand area located nearby the gas hydrate exploration area is used to AVO analysis, As the results of AVO modeling, type III AVO anomaly confirmed on the gas sand layer. The Castagna's equation constant value for estimating the S-wave velocity are evaluated as A=0.86190, B=-3845.14431 respectively and water saturation ratio is 50%. To calculate the reflection coefficient of synthetic seismogram, the Zoeppritz equation is used. For AVO inversion process, the dataset provided by Hampson-Rushell CO. is used.
한국 대륙붕 VI-1광구 고래 II지역의 3D탄성파 자료해석
신국선,유강민,김건득,엄창렬,Shin Kook Sun,Yu Kang Min,Kim Kun Deuk,Um Chang Lyeol 한국석유지질학회 1997 한국석유지질학회지 Vol.5 No.1
연구지역인 고래 II지역은 한반도 동남쪽 육지에 근접해 있으며 울릉분지(쓰시마분지)의 서남부에 위치한다. 동지역에 대한 3D탐사는 2D탐사에 의해 기확인된 구조들의 정밀평가를 목적으로 시행되었으며, 동작업의 일환으로 울릉분지의 층서 및 구조의 정밀분석이 시행되었다. 동지역은 기반암이 얕고 울릉분지의 구조운동이 모두 영향을 미친 지역으로 고해상도의 기반암지역 자료를 토대로 기반암을 포함하는 구조운동 및 층서와의 상관관계가 분석되었다. 3D 탄성파 자료 해석결과, 본 지역에는 조구조운동과 성인적 연관을 가진 8개의 건층면이 관찰되고 있다. 연구지역에서 관찰되는 지질구조는 분지형성초기에 형성된 블록단층과 후기 마이오세 스러스트 및 플라이오세 렌치단층 등 세 종류의 단층이 관찰되며, 울룽곡분으로 불리는 완만한 향사가 발달되어 있다. 본 지역에서 상기 지질 구조와 관련된 퇴적 시퀀스로는 음향 기반암, 열개동시성 시퀀스(시퀀스 $A_1, A_2$), 후열개 시퀀스 (시퀀스 $B_1{\~}B_3$),횡압력 동시성 시퀀스 (시퀀스 C) ,후횡압력 시퀀스 (시퀀스 D)등이 인지되었다. 각 시퀀스에 대해 구조도, 등시선도 등이 작성되어 상분석, 퇴적환경 해석작업이 이루어 졌다. 조구조운동 및 퇴적물 공급량에 따른 상대 해수면 변화와 관련하여 발달한 본 지역 시퀀스의 해석 결과, 울릉분지는 여러 형태의 조구조운동 및 퇴적물공급에의해 형성된 복합적인 분지의 층서 및 구조 양상을 나타낸다. The Gorae II area is located in the southwestern margin of the Ulleung Basin, East Sea and corresponds to the Ulleung Trough. The survey of 3D seismic data in this area was performed to delineate the structural leads confirmed by the previous 2D seismic data. As a part of 3D interpretation, basement related structural movements and their relationship with the stratigraphy were studied. The study shows that eight sequences were identified which are genetically related to the tectonics and sediment supply in this area. The geologic structures characterizing the study area consist of : (1) block faults developed in the early stage of basin opening, (2) late Miocene thrusts, and (3) Pliocene wrench faults. The eight sequences consist of pre-rift (acoustic basement), syn-rift (Sequence $A_1, A_2$), post-rift (Sequence $B_1{\~}B_3$), syn-compressional sequence (Sequence C), and post-compressional sequence(Sequence D) from oldest to youngest. The time structure and isochron maps were constructed for each sequence and also used in seismic facies analysis and interpretation of sedimentary environment. The interpretation results reveal that the relative sea level changes caused by several stages of tectonic movements and sediment supply control the stratal and structural geometry of Ulleung basin.