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N. Satyavani Kalachand Sain Malcolm Lall B. J. P. Kumar 《Marine Geophysical Researches》2008,29(3):167-175
Seismic data from the Andaman offshore region has been examined to investigate for the presence of gas hydrates. The seismic
data displays reflection characteristics such as blanking, enhanced reflection patterns, shadows in instantaneous frequency,
and increase in amplitude with the offset, which are indicative of gas hydrates and underlying free gas. A prominent bottom-simulating
reflection, BSR, coupled with reverse polarity is observed around 650–700 ms. Seismic attributes such as the reflection strength
and instantaneous frequency are computed along this reflector in order to probe for the presence of gas hydrates or free gas
in this region. The reflection plot shows a strong reflector paralleling the seafloor. In addition, attenuation of the high
frequency signal is noticed, indicating the presence of free gas below the BSR. 相似文献
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天然气水合物地震勘探的实际工作,需要在三维空间对天然气水合物矿体进行精细刻画,为此必须获得高分辨率的地震资料,而反褶积处理是提高地震资料分辨率的主要手段之一。本研究设计的改进子波反褶积算法,对地震记录的对数功率谱进行滤波,不但可有效识别BSR,同时可克服反射系数非白噪声的影响;采用谱间的互相关平均代替算术平均,可有效提高地震资料的分辨率;在提取子波的过程中,采用希尔伯特变换算法,提取子波简单、方便。通过对南海北部海域HS621测线的地震数据进行处理,证明该算法不但能稳定、清晰地追踪BSR,并且能有效地提高地震数据分辨率,满足天然气水合物地震资料精细处理的要求。 相似文献
24.
天然气水合物地震似海底反射现象AVO正演模型研究 总被引:10,自引:3,他引:7
似海底反射(BSR)现象是用人工地震方法识别含天然气水合物沉积地层的重要标志之一。针对水合物沉积物的悬浮、颗粒接触和胶结3种微观模式,进行了似海底反射现象正演模型的研究,考查了BSR现象产生的地震地质原因和运用AVO判断游离气的适用性。研究结果表明:在地震合成记录的帮助下,结合AVO变化曲线,可以认为BSR的成因有两种情况。实际工作中需要运用多种信息的综合分析而不是一种简单固定的模式来解释BSR的复杂成因。水合物沉积的3种微观模式都存在水合物的临界饱和度,当介质中水合物饱和度小于临界饱和度时,可以通过AVO曲线的变化形态来判断水合物沉积层下伏介质中是否含有游离气;而大于临界饱和度时,AVO技术则难以适用。AVO曲线形态、BSR现象与游离气三者之间存在复杂的关系,同样需要通过多种信息的综合分析来解释。 相似文献
25.
Abstract. Multi-channel seismic data obtained from the Nankai accretionary prism and forearc basin system has been studied to elucidate the migration and accumulation process of gas to the BGHS and examine the distribution pattern of BSRs and characteristic reflections associated with them.
BSRs are distributed widely in the Nankai accretionary prism and associated forearc basins (33,000 km2 ) and 90 % of them have migration and recycling origins. The widest distribution of the BSRs can be seen at the prism. A correlation between the BSR distributions and prism size shows that the BSRs tend to be more well-developed in a prism of large size. This suggests that a large prism may produce much amount of gas-bearing fluids that migrate to the BGHS and form the BSRs (tectonic control), hi the forearc basins, the BSRs are identified at topographic highs, anticlines and basin margins (structural control).
The upward migration of gas-bearing fluids is carried out through permeable sand layers and as a result, the distribution of BSRs is confined to alternating beds of sand and mud facies (sedimentary control). However, if there is enough time for upward migration and accumulation of gas to the BGHS, the BSRs can be generated widely in low-permeable mud facies (time control).
Those results imply that structural, tectonic, sedimentary and time controls are primary factors to decide the distribution of BSRs in the Nankai Trough area. 相似文献
BSRs are distributed widely in the Nankai accretionary prism and associated forearc basins (33,000 km
The upward migration of gas-bearing fluids is carried out through permeable sand layers and as a result, the distribution of BSRs is confined to alternating beds of sand and mud facies (sedimentary control). However, if there is enough time for upward migration and accumulation of gas to the BGHS, the BSRs can be generated widely in low-permeable mud facies (time control).
Those results imply that structural, tectonic, sedimentary and time controls are primary factors to decide the distribution of BSRs in the Nankai Trough area. 相似文献
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Overview of the MITI Nankai Trough Wells: A Milestone in the Evaluation of Methane Hydrate Resources 总被引:4,自引:0,他引:4
Yoshihiro Tsuji Hisashi Ishida Masaru Nakamizu Ryo Matsumoto Satoshi Shimizu 《Resource Geology》2004,54(1):3-10
Abstract. Bottom-simulating reflectors suggestive of the presence of methane hydrates are widely distributed below the ocean floor around Japan. In late 1999, drilling of the MITI Nankai Trough wells was conducted to explore this potential methane hydrate resource and a Tertiary conventional structure. The wells are located in the Northwest Pacific Ocean off Central Japan at a water depth of 945 m. A total of six wells were drilled, including the main well, two pilot wells, and three post survey wells at intervals of 10–100 m. All wells except the first confirmed the occurrence of hydrates based on logging-while-drilling, wire-line logging and/or coring using a pressure and temperature coring system in addition to conventional methods. Based on the various well profiles, four methane hydrate-bearing sand-rich intervals in turbidite fan deposits were recognized. Methane hydrates fill the pore spaces in these deposits, reaching saturation of up to 80 % in some layers. The methane hydrate-bearing turbiditic sand layers are less than 1 m thick, with a total thickness of 12–14 m. The bottom depth of high hydrate concentration correlates well with the depth of the bottom-simulating reflector. Based on these exploration results, the Japanese government inaugurated a 16-year methane hydrate exploitation program in 2001. 相似文献
27.
天然气水合物(gas hydrates)作为一种新的潜在能源 是目前世界范围内研究的热点和难点之一。目前 普遍认为拟海底反射(简称BSR)是天然气水合物存 在的重要标志之一,但有关水合物的识别仍有很 多问题需要解决。例如世界各地已发现水合物的 例证表明在没有BSR的情况下仍然存在水合物,在 没有BSR的情况下如何识别水合物仍是没有解决 的研究课题。本文以天然气水合物的识别为研究 目的,以AVO属性交汇图为研究手段,通过双相介 质正演理论模型研究了当地层含有天然气水合物 或游离气时的AVO属性特征,并与由双相介质的 交错网格有限差分法得到的合成地震记录所反演 得出的AVO交汇图进行了对比,得到高度一致的 对比结果,表明利用AVO属性交汇图是识别天然 气水合物和游离气并能估测其含量的有效技术。 相似文献
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Bo Y. Yi Gwang H. Lee Senay Horozal Dong G. Yoo Byong J. Ryu Nyeon K. Kang Sung R. Lee Han J. Kim 《Marine and Petroleum Geology》2011,28(10):1953-1966
The presence of gas hydrate in the Ulleung Basin, East Sea (Japan Sea), inferred by various seismic indicators, including the widespread bottom-simulating reflector (BSR), has been confirmed by coring and drilling. We applied the standard AVO technique to the BSRs in turbidite/hemipelagic sediments crosscutting the dipping beds and those in debris-flow deposits to qualitatively assess the gas hydrate and gas concentrations. These BSRs are not likely to be affected by thin-bed tuning which can significantly alter the AVO response of the BSR. The BSRs crosscutting the dipping beds in turbidite/hemipelagic sediments are of low-seismic amplitude and characterized by a small positive gradient, indicating a decrease in Poisson’s ratio in the gas-hydrate stability zone (GHSZ), which, in turn, suggests the presence of gas hydrate. The BSRs in debris-flow deposits are characterized by a negative gradient, indicating decreased Poisson’s ratio below the GHSZ, which is likely due to a few percent or greater gas saturations. The increase in the steepness of the AVO gradient and the magnitude of the intercept of the BSRs in debris-flow deposits with increasing seismic amplitude of the BSRs is probably due to an increase in gas saturations, as predicted by AVO model studies based on rock physics. The reflection strength of the BSRs in debris-flow deposits, therefore, can be a qualitative measure of gas saturations below the GHSZ. 相似文献
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S. Chand L. RiseJ. Knies H. HaflidasonB.O. Hjelstuen R. Bøe 《Marine and Petroleum Geology》2011,28(7):1350-1363
The Cenozoic seismic stratigraphy and geological development of the south Vøring margin are analyzed to understand their relation to fluid flow and margin stability. The regional stratigraphy and palaeomorphology of the Møre and Vøring basins indicate gradual changes in depositional environment and tectonic compression between 55 Ma to 2.8 Ma during Brygge and Kai periods, and abrupt changes associated with glacial/interglacial cycles from last 2.8 Ma during Naust period. These changes resulted in deposition of various types of sediments and led to processes such as polygonal faulting and dewatering, inter-fingering of contouritic, stratified and glacigenic sediments, and margin progradation.A gas hydrate related bottom simulating reflector (BSR) occurs at Nyegga and within the central Vøring Basin while pockmarks are observed at Nyegga only. Diagentic reflectors due to Opal A - Opal CT conversion (DBSRs) occur along a wider area beyond the shelf edge. The DBSRs are located in oozes within the Kai and late Brygge Formations. The gas hydrate BSR occurrence is concentrated above Eocene depocenters in hemipelagic and contouritic sediments deposited during Late Plio-Pleistocene. The BSR overlies polygonal faults and DBSRs but are confined to the slope of anticlines indicating its formation being related to fluid pathways from methanogenic rocks through focused fluid flow. Microbial gas production in Kai, Brygge and deeper formations may have supplied the gas for gas hydrate formation. Fluid expulsion due to DBSR formation and polygonal faulting in oozes may have created overpressure development in permeable layers belonging to the overlying Naust Formation. Slide headwalls are also located close to the anticlines in the study area, implying that over pressured oozes and focussed fluid flow may have been important in creating weak surfaces in the overlying Naust sediments, promoting conditions for failures to occur. 相似文献
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四川盆地东北部三叠系飞仙关组硫酸盐还原作用对碳酸盐成岩作用的影响 总被引:15,自引:0,他引:15
四川盆地东北部三叠系飞仙关组存在广泛的硫酸盐还原作用,同时地层中也存在锶含量异常高的成岩流体。研究表明:热化学硫酸盐还原作用(TSR)和(或)细菌硫酸盐还原作用(BSR)造成的SO42-离子的消耗对成岩孔隙流体中SrSO4溶解度的改变是三叠系中高Sr成岩流体的形成机制之一,该机制使得孔隙流体从白云石化作用和碳酸盐矿物的新生变形作用中获得的Sr在流体中以高浓度的Sr2+形式存在,并使之在流体中极度富集,这也是四川盆地东北部三叠系中大型和超大型天青石矿床的形成机制之一。H2S和CO2是硫酸盐还原作用的重要产物,不同温度条件下溶于水中的H2S和CO2,与不溶于水的气体分子之间的平衡反应H2S(aq)H2S(g)和CO2(aq)CO2(g)的平衡常数和吉布斯自由能增量计算表明,当温度从25℃升高至220℃时,两个反应的平衡常数分别大致从10增至240和从20增至500,两个反应的平衡常数都始终大于1,说明H2S和CO2更趋向于以气体形式存在,同时温度越高,系统中以气体形式存在的H2S和CO2会越多,溶解于水中的H2S和CO2会越少,因而在深埋藏的高温条件下,H2S和CO2对碳酸盐矿物的溶解能力可能相对很小。相对低温的成岩环境、高温流体的向上和侧向运移、构造抬升、富氧流体与含有H2S流体的混合以及金属硫化物的沉淀是提高含H2S和(或)CO2流体对碳酸盐矿物溶解能力的五个途径。因此,与较早成岩阶段相对浅埋藏环境的碳酸盐溶解作用有关的H2S和CO2流体可能与细菌硫酸盐还原作用(BSR)关系更为密切;断层或其它流体运移通道是高温含有H2S和CO2流体向上运移的基础条件,具有原生孔隙度和渗透率的礁、滩相高能沉积物也是流体发生侧向运移的先决条件;大幅度的构造抬升造成的地层温度降低是提高含H2S和(或)CO2地层流体对碳酸盐矿物溶解能力的重要因素,地壳抬升至近地表造成的古喀斯特作用也可以为H2S的氧化提供良好的地质环境。在有关的勘探中应注意:在断层等流体运移通道造成高温含H2S和CO2流体向上运移的条件下,与之有关的构造低点应该是主要的勘探目标;在燕山运动导致的地层抬升并导致深部热流体降温的条件下,与之有关的构造高点应该是主要的勘探目标,应分别对待。 相似文献