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1.
实际地下储层是含流体的双相介质,常规的弹性波叠前逆时偏移多基于单相介质理论,不能充分考虑地层中的双相介质对地震波场的影响。为研究双相介质中地震波传播对逆时偏移结果的影响,基于Biot的双相介质理论实现了一阶速度-应力双相介质方程的逆时偏移,并基于CUDA实现了双相介质方程逆时偏移的GPU加速。模型实验结果表明,在含流体的双相介质中,双相介质方程逆时偏移的结果比弹性波方程和声波方程的结果更接近真实的构造形态,同时与基于CPU的双相介质逆时偏移相比,基于GPU的逆时偏移可达到27倍的加速比。因此基于GPU加速的双相介质逆时偏移不仅能够实现对双相介质地层的精确偏移成像,而且能够有效提高逆时偏移的计算效率。 相似文献
2.
针对南海神狐海区含天然气水合物的高孔隙度、以粉砂质黏土为主的未固结的深水沉积地层,采用Lee提出的改进的Biot-Gassmann(BGTL)模型,利用纵波速度数据估算了A井天然气水合物的饱和度。BGTL模型假设非固结沉积地层的横波速度与纵波速度比与地层骨架的横波速度与纵波速度比与地层孔隙度有关。模型中参数的选择与天然气水合物在沉积物中的赋存方式、沉积物的矿物组成、地层压差、孔隙度及微观孔隙结构等参数密切相关。A井中天然气水合物在沉积物中赋存模式接近于颗粒骨架支撑模式。根据岩心分析资料将A井的矿物骨架简化为黏土矿物、碳酸盐、陆源碎屑3类,根据各矿物组分的理论弹性参数和体积百分比可以计算得到地层骨架的弹性模量和密度。应用BGTL理论估算得到的A井天然气水合物主要赋存于海底以下195~220mbsf井段,饱和度多数为20%~40%,最大饱和度为47%左右,与实测结果吻合。 相似文献
3.
天然气水合物作为潜能巨大、资源量丰富、燃烧值高的未来新能源,但由于其特殊的物理力学性质和赋存状态,经济开采技术仍面临诸多难题.本文以全球勘探发现存在天然气水合物的地区为基础,介绍了全球主要水合物的海陆资源分布及开采难易程度;以主要影响天然气水合物开采方式选择因素为基础,分析了天然气水合物在地层中的赋存类型、成藏模式和储... 相似文献
4.
《海洋地质与第四纪地质》2017,(5)
饱和度是评价天然气水合物资源量的重要参数之一,不同海域由于水合物微观赋存状态差异,评价方法不同。大量水合物钻探取心显示在珠江口盆地不同海域发现了不同类型的水合物,在东部海域发现了呈脉状、块状、结核状等裂隙内形成肉眼可视的水合物,而神狐海域发现了呈分散状充填在孔隙空间不同饱和度的水合物,两种不同类型水合物层的测井异常响应特征不同,评价饱和度方法不同。研究表明东部海域基于各向异性电阻率模型估算的水合物饱和度与压力取心吻合,近海底发育的水合物层饱和度相对较低,约为10%,而基于各向同性模型估算水合物饱和度高达60%,远大于压力取心饱和度。在碳酸盐岩层,基于未固结地层各向同性与各向异性估算水合物饱和度大于氯离子异常估算水合物饱和度,而利用胶结模式估算水合物饱和度与氯离子吻合。利用地震资料,以测井为约束利用稀疏脉冲反演地层的速度或波阻抗,结合不同岩石物理模型分析,再通过线性拟合或循环迭代方法可以估算水合物饱和度体,研究水合物的空间分布。通过沿稳定带底界提取水合物饱和度属性,发现神狐海域水合物呈不均匀分布,在局部峡谷脊部呈条带状特征。 相似文献
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海洋拖缆主动源多道地震技术是应用于海洋天然气水合物资源调查的主要技术方法。不同于常规油气藏勘探,海底天然气水合物成藏机制复杂多样,海底似反射(Bottom Simulating Reflector,BSR)特征与水合物赋存并非完全对应。为提高海洋天然气水合物矿体识别的可靠性,地震属性技术在水合物资源调查中发挥着越来越重要的作用。本文对我国南海北部海域天然气水合物调查中的关键属性进行了对比、分析及筛选试验研究。试验针对海洋高分辨多道三维地震数据,采用三维地震层速度控制综合处理技术完成了BSR区域的成像,提取了与BSR相关的多种地震属性,并对BSR地震属性体的内部特性进行了分析,实现了BSR特征水合物矿体的识别,并提取了BSR上方和下部结合层带的地震属性。研究结果表明,在水合物赋存地层极其复杂的条件下,地震属性分析技术在海洋复杂浅地层水合物识别方面具有可行性和技术优势。 相似文献
7.
为实现天然气水合物开采过程中水合物层分解状态实时监测,基于静电场理论和监测井布设特点设计了一套电极阵列式井中电学监系统。以南海神狐海域天然气水合物远景开采区为研究区,总结归纳水合物开采过程储层分解和电阻率变化特点,构建不同开采阶段储层地质及电阻率模型,模拟利用设计系统对水合物层进行探测,正演计算得到不同装置形式探测电阻率剖面图像,随后对图像进行对比分析,界定该系统对水合物层分解状态的探测能力。研究结果表明,利用偶极装置探测的电阻率和相对电阻率剖面可准确确定不同饱和度水合物层界面位置,水合物分解区范围,分解区边界定位误差可小于0.5m。井中阵列式电学监测系统能够有效进行水合物层分解状态监测,具有良好的应用前景。 相似文献
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深海环境泥火山活动为甲烷从深部向浅部迁移提供了搬运介质和通道,泥火山附近天然气水合物成藏具有独特的形成过程和富集规律。泥火山型水合物资源潜力和环境影响的理论假设已被提出,而在工程实施阶段的论述相对较少。本次研究通过调研世界范围内典型海域泥火山-天然气水合物系统研究进展和赋存规律,结合我国海域泥火山的调查成果,归纳出泥火山型天然气水合物赋存地质模型。之后分析该模型组成要素的地质记录,获得识别泥火山型天然气水合物的3G异常标志,总结出该类型水合物实用的勘探思路。 相似文献
10.
沉积层中水合物分解可能引起多种形式的地质灾害.针对水合物加热分解.尤其是快速加热条件下,可能引起的沉积层破坏方式及破坏条件进行了模型实验.模型实验分别在一个矩形模型箱中和一个圆柱形模型箱中进行,以模拟二维和一维情况.实验结果表明,随着水合物分解条件(如缓慢加热、快速加热)和水合物沉积层与覆盖层情况的变化(如地层非均匀、... 相似文献
11.
M. W. Lee D. R. Hutchinson W. F. Agena W. P. Dillon J. J. Miller B. A. Swift 《Marine Geophysical Researches》1994,16(3):163-184
Gas hydrates are stable at relatively low temperature and high pressure conditions; thus large amounts of hydrates can exist in sediments within the upper several hundred meters below the sea floor. The existence of gas hydrates has been recognized and mapped mostly on the basis of high amplitude Bottom Simulating Reflections (BSRs) which indicate only that an acoustic contrast exists at the lower boundary of the region of gas hydrate stability. Other factors such as amplitude blanking and change in reflection characteristics in sediments where a BSR would be expected, which have not been investigated in detail, are also associated with hydrated sediments and potentially disclose more information about the nature of hydratecemented sediments and the amount of hydrate present.Our research effort has focused on a detailed analysis of multichannel seismic profiles in terms of reflection character, inferred distribution of free gas underneath the BSR, estimation of elastic parameters, and spatial variation of blanking. This study indicates that continuous-looking BSRs in seismic profiles are highly segmented in detail and that the free gas underneath the hydrated sediment probably occurs as patches of gas-filled sediment having variable thickness. We also present an elastic model for various types of sediments based on seismic inversion results. The BSR from sediments of high ratio of shear to compressional velocity, estimated as about 0.52, encased in sediments whose ratios are less than 0.35 is consistent with the interpretation of gasfilled sediments underneath hydrated sediments. This model contrasts with recent results in which the BSR is explained by increased concentrations of hydrate near the base of the hydrate stability field and no underlying free gas is required. 相似文献
12.
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
13.
Jin Qian Xiu-Juan Wang Shi-Guo Wu Zhen-zhen Wang Sheng-Xiong Yang 《Marine Geophysical Researches》2014,35(2):125-140
Gas hydrates have been identified from two-dimensional (2D) seismic data and logging data above bottom simulating reflector (BSR) during China’s first gas hydrate drilling expedition in 2007. The multichannel reflection seismic data were processed to be preserved amplitudes for quantitatively analyzing amplitude variation with offset (AVO) at BSRs. Low P-wave velocity anomaly below BSR, coinciding with high amplitude reflections in 2D seismic data, indicates the presence of free gas. The absolute values of reflection coefficient versus incidence angles for BSR range from 0 to 0.12 at different CMPs near Site SH2. According to logging data and gas hydrate saturations estimated from resistivity of Site SH2, P-wave velocities calculated from effective media theory (EMT) fit the measured sonic velocities well and we choose EMT to calculate elastic velocities for AVO. The rock-physics modeling and AVO analysis were combined to quantitatively assess free gas saturations and distribution by the reflection coefficients variation of the BSRs in Shenhu area, South China Sea. AVO estimation indicates that free gas saturations immediately beneath BSRs may be about 0.2 % (uniform distribution) and up to about 10 % (patchy distribution) at Site SH2. 相似文献
14.
Small amounts of free gas in interstitial sediment pores are known to significantly lower compressional (P-) wave velocity (Vp). This effect, combined with moderately elevated Vp from the presence of gas hydrates, is usually thought to be the cause for the often observed strong negative reflection coefficients of bottom simulating reflections (BSRs) at the base of gas hydrate stability (BGHS). At several locations however, weak BSRs have been observed, which are difficult to reconcile with a presence of gas in sediment pores. We here present a rock physics model for weak BSRs on the Hikurangi Margin east of New Zealand. Thin sections of a fine-grained mudstone sample from a submarine outcrop in the vicinity of a weak BSR show macroscopic porosity in the form of fractures and intrafossil macropores. We apply the Kuster-Toksöz theory to predict seismic velocities for a rock with water-saturated interstitial micropores and gas or hydrates in macroscopic pore space simulating fractures or compliant macropores. We match field observations of a weak BSR with a reflection coefficient of −0.016 with two end-member models; (1) rocks with gas hydrate-filled voids with a concentration of <4% of bulk sediment overlying water-filled voids, or (2) fully gas-saturated voids at a concentration of <2% beneath water-filled voids. A natural system is likely to consist of a combination of these end-members and of macroporosity filled with a mixture of water and gas or hydrate. Our results suggest weak BSRs may be caused by gas hydrate systems in fractures and macropores of fine-grained sediments with fully water-saturated interstitial pore space. Gas may be supplied into the macroscopic pore space by diffusion-driven short-range migration of methane generated within the gas hydrate stability field or, our favoured model based on additional geologic considerations, long-range advective migration from deeper sources along fractures. 相似文献
15.
《Marine Geology》2001,172(1-2):1-21
In this paper we present and discuss the frequency-dependent behaviour of the acoustic characteristics of methane hydrate-bearing sediments in Lake Baikal, Siberia. Five different types of seismic sources (airgun-array, two types of single airguns, watergun and sparker) are used, encompassing a frequency bandwidth from 10 up to 1000 Hz. On low-frequency airgun-array data, the base of the hydrate stability zone (HSZ) is observed as a high-amplitude bottom-simulating reflection (BSR) with reversed polarity. The amplitude and continuity of the BSR decrease or even disappear on medium- to high-frequency data, a feature explained in terms of vertical and horizontal resolution. The increasing reflection amplitude of the BSR with increasing offset, the calculated reflection coefficient of the BSR and the occurrence of enhanced reflections below the BSR suggest the presence of free gas below the HSZ. The observation of some enhanced reflections extending above the BSR may be interpreted as an indication for free gas co-existing with hydrates within the HSZ. Amplitude blanking above the BSR is highly variable while the BSR itself appears to act as a low-pass frequency filter for medium- to high-frequency data.New single-channel airgun profiles provide the first seismic information across the Baikal Drilling Project (BDP-97) deep drilling site, at which hydrate-bearing sediments were retrieved at about 200 m above the base of the local HSZ. At the drilling site there are no seismic characteristics indicative of the presence of hydrates. Combination of the drilling and seismic information has allowed us to make a rough estimation of the volume of hydrates and carbon stored in the sediments of Lake Baikal, which lead us to conclude that the Lake Baikal gas hydrate reservoirs do not form a prospective energy resource. 相似文献
16.
Characteristics of Gas Hydrate and Free Gas Offshore Southwestern Taiwan from a Combined MCS/OBS Data Analysis 总被引:2,自引:0,他引:2
In this study, we present the results of the combined analyses of ocean bottom seismometer and multi-channel seismic reflection data collection offshore southwestern Taiwan, with respect to the presence of gas hydrates and free gas within the accretionary wedge sediments. Estimates of the compressional velocities along EW9509-33 seismic reflection profile are obtained by a series of pre-stack depth migrations in a layer stripping streamlined Deregowski loop. Strong BSR is imaged over most of the reflection profile while low velocity zones are imaged below BSR at several locations. Amplitude versus angle analysis that are performed within the pre-stack depth migration processes reveal strong negative P-impedance near the bottom of the hydrate stability zone, commonly underlain by sharp positive P impedance layers associated with negative pseudo-Poisson attribute areas, indicating the presence of free gas below the BSR. Ray tracing of the acoustic arrivals with a model derived from the migration velocities generally fits the vertical and hydrophone records of the four ocean-bottom seismographs (OBS). In order to estimate the Poisson’s ratios in the shallow sediments at the vicinity of the OBSs, we analyze the mode-converted arrivals in the wide-angle horizontal component. P-S mode converted reflections are dominant, while upward P-S transmissions are observed at large offsets. We observe significant compressional velocity and Poisson’s ratio pull-down in the sediment below the BSR likely to bear free gas. When compared to Poisson’s ratio predicted by mechanical models, the values proposed for the OBSs yield rough estimates of gas hydrate saturation in the range of 0–10% in the layers above the BSR and of free gas saturation in the range of 0–2% just below the BSR. 相似文献
17.
An analysis of 3D seismic data from the northwestern part of the Ulleung Basin, East Sea, revealed that the gas hydrate stability zone (GHSZ) consists of five seismic units separated by regional reflectors. An anticline is present that documents activity of many faults. The seismic indicators of gas hydrate occurrence included bottom simulating reflector (BSR) and acoustic blanking in the gas hydrate occurrence zone (GHOZ). By the analysis of the seismic characteristics and the gradient of the sedimentary strata, the GHOZ was divided into four classes: (1) dipping strata upon strong BSR, (2) dipping strata below strong BSR, (3) parallel strata with acoustic blanking, and (4) parallel strata below weak BSR. Seismic attributes such as reflection strength and instantaneous frequency were computed along the GHOZ. Low reflection strength and high instantaneous frequency were identified above the BSR, indicating the occurrence of gas hydrate. A remarkably high reflection strength and low instantaneous frequency indicated the presence of free gas below the BSR. Considering the distribution of the gas hydrate and free gas, two gas migration processes are suggested: (1) stratigraphic migration through the dipping, permeable strata and (2) structural migration from below the GHSZ along faults. 相似文献
18.
The occurrence of gas hydrate has been inferred from the presence of Bottom-Simulating Reflectors (BSRs) along the western
continental margin of India. In this paper, we assess the spatial and vertical distribution of gas hydrates by analyzing the
interval velocities and Amplitude Versus Offset (AVO) responses obtained from multi-channel seismics (MCSs). The hydrate cements
the grains of the host sediment, thereby increasing its velocity, whereas the free gas below the base of hydrate stability
zone decreases the interval velocity. Conventionally, velocities are obtained from the semblance analysis on the Common Mid-Point
(CMP) gathers. Here, we used wave-equation datuming to remove the effect of the water column before the velocity analysis.
We show that the interval velocities obtained in this fashion are more stable than those computed from the conventional semblance
analysis. The initial velocity model thus obtained is updated using the tomographic velocity analysis to account for lateral
heterogeneity. The resultant interval velocity model shows large lateral velocity variations in the hydrate layer and some
low velocity zones associated with free gas at the location of structural traps. The reflection from the base of the gas layer
is also visible in the stacked seismic data. Vertical variation in hydrate distribution is assessed by analyzing the AVO response
at selected locations. AVO analysis is carried out after applying true amplitude processing. The average amplitudes of BSRs
are almost constant with offset, suggesting a fluid expulsion model for hydrate formation. In such a model, the hydrate concentrations
are gradational with maxima occurring at the base of hydrate stability zone. 相似文献
19.
2D and 3D seismic reflection and well log data from Andaman deep water basin are analyzed to investigate geophysical evidence related to gas hydrate accumulation and saturation. Analysis of seismic data reveals the presence of a bottom simulating reflector (BSR) in the area showing all the characteristics of a classical BSR associated with gas hydrate accumulation. Double BSRs are also observed on some seismic sections of area (Area B) that suggest substantial changes in pressure–temperature (P–T) conditions in the past. The manifestation of changes in P–T conditions can also be marked by the varying gas hydrate stability zone thickness (200–650 m) in the area. The 3D seismic data of Area B located in the ponded fill, west of Alcock Rise has been pre-stack depth migrated. A significant velocity inversion across the BSR (1,950–1,650 m/s) has been observed on the velocity model obtained from pre-stack depth migration. The areas with low velocity of the order of 1,450 m/s below the BSR and high amplitudes indicate presence of dissociated or free gas beneath the hydrate layer. The amplitude variation with offset analysis of BSR depicts increase in amplitude with offset, a similar trend as observed for the BSR associated with the gas hydrate accumulations. The presence of gas hydrate shown by logging results from a drilled well for hydrocarbon exploration in Area B, where gas hydrate deposit was predicted from seismic evidence, validate our findings. The base of the hydrate layer derived from the resistivity and acoustic transit-time logs is in agreement with the depth of hydrate layer interpreted from the pre-stack depth migrated seismic section. The resistivity and acoustic transit-time logs indicate 30-m-thick hydrate layer at the depth interval of 1,865–1,895 m with 30 % hydrate saturation. The total hydrate bound gas in Area B is estimated to be 1.8 × 1010 m3, which is comparable (by volume) to the reserves in major conventional gas fields. 相似文献
20.
Multi-channel seismic reflection data from the western continental margin of India (WCMI) have been analyzed to construct a plausible model for gas hydrate formation. A reflector at 2950 ms two way travel time (TWT) on one of the sections is interpreted to represent the base of the layer of the methane hydrate, identified by a bottom simulating reflector (BSR) that lies almost 500 ms beneath the sea floor. BSRs of similar origin are common world wide, where they are usually interpreted to mark the base of gas hydrate bearing clastic sediment, with or without underlying free gas. In this study we present a model with the contrasting physical properties that produce synthetic wavelets that match with the observed BSR amplitude and waveforms for varying source-receiver offsets of multi-channel seismic reflection data. The preliminary results presented here put important constraints on models that predict the distribution and formation of hydrate. Offset-dependent amplitude recovery also gives an appropriate response for hydrate characterization. 相似文献