中建南盆地北部海底麻坑地貌特征及成因机制

海底麻坑是与流体逸散相关的一种海底凹陷地貌, 在全球海域的陆架、陆坡和深海平原等均有广泛发育。文章利用高分辨率的多波束测深数据和三维地震资料, 在中建南盆地北部识别出330个规模不等的海底麻坑, 按照麻坑形态可将其分为: 圆形、椭圆形、长条形及新月形麻坑。研究区内海底麻坑直径可达1500~7900m, 最大深度可达175m, 其中圆形麻坑规模(直径、深度)小于椭圆形、长条形和新月形麻坑, 表明圆形麻坑处于麻坑发育早期阶段。三维地震资料显示不同类型海底麻坑的下伏地层中均发育有断层、气烟囱、裂隙等流体逸散通道, 为该区域海底麻坑形成提供了有利条件。在海底麻坑演化过程中, 底流对海底麻坑的地貌形态具有改造作用。当圆形麻坑下伏地层流体活动强烈时, 流体可沿着运移通道直接向麻坑内壁渗漏, 使得其内壁塌陷, 逐渐演化成椭圆形麻坑。由于椭圆形麻坑处于底流活动影响的早期阶段, 其受底流改造作用较弱。在持续性底流活动的强烈改造作用下, 紧密排列的圆形或椭圆形麻坑逐渐拉伸演变成长条形麻坑。当底流作用于孤立的圆形麻坑时, 在底流的上游侧沉积速率增加, 麻坑在上游侧接受沉积被掩埋, 下游侧地层被侵蚀, 从而形成新月形麻坑。根据研究区海底麻坑成因机制分析, 文章首次提出了一种展示中建南盆地不同类型海底麻坑演化过程模型, 该模型有助于理解中建南盆地流体逸散过程和底流活动, 并且可为其他区域海底麻坑演化过程研究提供参考。     

西非下刚果盆地海底麻坑特征及与盐岩活动的关系

以高精度三维地震资料为基础,系统研究了下刚果盆地深海麻坑的形态特征及其与盐构造活动的关系。研究发现,该区海底麻坑几何形态主要有平面上圆形、剖面上深V型和平面上条形、剖面浅U型两大类,并分别分布于由浅水到深水的东西两个不同区带。进一步分析认为,该区麻坑的发育、分布与下部盐岩构造活动有密切关系,东部盐岩底辟构造带上发育由压扭应力作用下的海底地层挤压破裂并诱发流体高压喷射而形成的深V型麻坑,西部盐岩挤压逆冲构造带上发育由拉张应力作用下的沿盐岩体边界上海底地层拉张破裂而形成的U型麻坑。该区产生麻坑的海底地层破裂和流体高压均由下部盐岩构造活动所控制。     

南海礼乐盆地海底麻坑地貌及成因分析

本文基于高分辨率多波束测深和浅地层剖面数据,首次对南海礼乐盆地南部坳陷海底麻坑进行了系统的识别研究。共识别出各类麻坑81个,其中麻坑直径最大约2.4 km,坑深最大约157 m。麻坑种类多样:按平面形态主要分为圆形、椭圆形、拉长形和新月形麻坑;按组合方式分为孤立麻坑、链状麻坑和复合麻坑;按直径分为正常麻坑和大型麻坑。区域内发育多条大型海底峡谷,峡谷侵蚀引起两侧地层稳定性降低,气体储层遭受破坏,泄露的气体沿断层或气烟囱等喷发出海底形成麻坑。而因麻坑生成时剥蚀的沉积物质与周围水体混合并逐渐发展成浊流,在一定程度上促进海底峡谷向下延伸。研究区内单个麻坑的平面形态最初为圆形或椭圆形,之后由于重力流和峡谷侵蚀的影响,逐渐发展成拉长形或新月形,麻坑之间也会发生组合形成复合麻坑。链状麻坑与冲沟的形成联系密切,沿垂直于等深线方向展布的链状麻坑在重力流的冲刷下,发育成底部平坦的麻坑冲沟。对比分析全球其他海域麻坑,发现海底麻坑尺寸与水深关系密切,在深水区域更容易发育大型麻坑。     

南海中建海域麻坑发育特征及成因机制

海底麻坑在圈定潜在的天然气水合物发育区和指示海底地质灾害方面都具有重要意义。基于南海中建海域的高密度三维地震资料,采用自动追踪技术对研究区海底地貌特征进行了刻画,发现了众多形态各异、大小不一的麻坑,可分为圆形麻坑、椭圆形麻坑、拉长形麻坑、新月形麻坑和复合型麻坑等5类。中建海域的海底麻坑主要发育在海底地形坡折的位置,成群、成带分布,在地形平坦的位置麻坑不发育。影响中建海域麻坑形成的因素主要有火山活动、断裂活动、水合物分解、海底底流等。引起中建海域海底形成麻坑的流体主要有4种,分别是火山热液、天然气水合物分解的气体、沿断裂向上运移的深部油气及火山热液与天然气水合物分解气体的混合。     

北黄海海底麻坑群形态的定量研究及控制因素

本文基于高分辨率多波束水深数据和反向散射强度数据,对北黄海海底麻坑群的形态参数进行定量研究,结合水深、地形坡度和后向散射强度的变化准确界定了麻坑的轮廓,识别出圆形、椭圆形、拉长型麻坑共282个,并在ArcGIS软件中对其形态参数进行了分析计算,麻坑的平均长轴1.36 km,短轴0.78 km,直径0.94 km,面积0.88 km2,平均周长3.82 km,长宽比1.83,深度0.3~2.5 m,平均面积密集度13%,麻坑的剖面形态有麻坑边缘凹陷、中部有明显凸起（W1型）,麻坑边缘凹陷、中部略凸起（W2型）,麻坑中部单纯凹陷（V型）,分别集中分布在麻坑群的北部、南部、西部。麻坑的平面规模大、深度小的原因与地层中形成麻坑的游离气体浓度较小有关,也可能受到了地震、海啸等外力的诱发。麻坑的长轴优势走向为ENE-WSW、NNE-SSW,底流对其形状的塑造起了较大作用,部分麻坑成串排列,形成串珠状的麻坑链,其排列方式受到海底古河道、古潟湖等沉积地层结构的控制。海底麻坑群发育区反向散射强度为-60~-71 dB,麻坑内部较麻坑外部平均高5 dB,可能为麻坑内部气体泄漏引起海底沉积物被剥蚀后残留下的粗颗粒物质或海底生物活动留下的遗迹导致的。     

南海北部陆架主要地貌特征及灾害地质因素

利用最新高精度多波束水深资料,对南海北部陆架地貌类型和特征进行了系统的识别和分析,发现研究区活动沙波、滑塌体、隆起脊、沟槽和麻坑等灾害地质因素发育。沙波多为直线型沙波,小、中、大型沙波均有发育,自北向南随着水深增大,沙波规模增大,沙波的活动性显著增强。底流内波特征变化与沙波规模和迁移情况具有一致性,沙波的形成和迁移与内波活动密切相关。根据滑塌特征地貌识别出7处滑塌,新老滑塌均有发育,新滑塌多呈线状延伸,梯状滑塌特征明显,分析认为新滑塌近期并无进一步滑动的趋势。受古岸线残留地貌控制,南部地形起伏较大,发育一系列隆起脊,K1—K4隆起脊近NE—SW走向平行排列,K5隆起脊为E—W走向与之相交。另外,研究区发育大量麻坑,直径30～100m,麻坑深度1.0～3.0m。     

加蓬海岸盆地海底麻坑的成因机制及对油气勘探的指示

海底麻坑是由于地下流体在高压下喷发而在海底形成的凹陷坑,可作为地下油气的直接指示。加蓬海岸盆地发现大量的海底麻坑,其地震反射同相轴表现为下拉特征,且地震反射振幅和相干属性均出现异常。该盆地海底麻坑的平面分布规律与下伏盐岩活动及盐岩展布有很大的相关性。通过对三维地震资料的解释,初步研究了加蓬海岸盆地海底麻坑的成因和形成模式。通过分析发现,该地区海底麻坑形成与下伏盐岩活动有关,盐底辟运动造成附近油气泄露产生相关气烟囱、亮点和海底麻坑等现象。海底麻坑可以成为下伏油气系统的直接指示,该地区的麻坑可以有效指示油气系统的展布范围和盐岩分布规律,预测断裂发育和有效圈闭带。对海底麻坑的深入研究有利于我们更好地优选勘探区带和区块,更好地了解研究区地下油气的分布规律。     

南海东北部陆坡海底微地貌特征及其天然气渗透模式

海底天然气渗漏是海洋环境中广泛分布的自然现象,在世界各大洋中都有发现。海底渗漏可以极大地改变海底地貌特征,形成多种与之相关的微地貌类型。海底渗漏和天然气水合物的赋存具有密切的关系,海底渗漏区常伴有埋藏浅、饱和度高的天然气水合物。对南海东北部陆坡海域浅地层剖面、多波束测探和地震反射剖面等资料进行综合研究,识别出海底麻坑、海底丘状体、大型海底圆丘、泥火山等与海底天然气渗漏有关的微地貌类型,且麻坑、海底丘状体/大型海底圆丘、泥火山微地貌分别代表了浅覆盖层快速天然气渗漏、浅覆盖层中等速度天然气渗漏和厚覆盖层快速天然气渗漏3种天然气渗漏模式。具有海底丘状体微地貌及声空白反射特征的浅层天然气聚集带,成为块状水合物最理想的发育场所,这可能称为南海北部陆坡勘察块状水合物的重要识别标志。     

南海东北陆坡海底微地貌特征及其天然气渗漏模式

海底天然气渗漏是海洋环境中广泛分布的自然现象,在世界各大洋中都有发现。海底渗漏可以极大地改变海底地貌特征,形成多种与之相关的微地貌类型。海底渗漏和天然气水合物的赋存具有密切的关系,海底渗漏区常伴有埋藏浅、饱和度高的天然气水合物。对南海东北部陆坡海域浅地层剖面、多波束测深和地震反射剖面等资料进行综合研究,识别出海底麻坑、海底丘状体、大型海底圆丘、泥火山等与海底天然气渗漏有关的微地貌类型,且麻坑、海底丘状体／大型海底圆丘、泥火山微地貌分别代表了浅覆盖层快速天然气渗漏、浅覆盖层中等速度天然气渗漏和厚覆盖层快速天然气渗漏3种天然气渗漏模式。以海底丘状体微地貌及声空白反射特征的浅层天然气聚集带,成为块状水合物最理想的发育场所,这可能成为南海北部陆坡勘察块状水合物的重要识别标志。     

渤海辽东湾海域海底底形特征及控制因素

基于我国海洋区域地质调查项目获取的水深、侧扫声呐、单道地震和浅地层剖面数据,结合前人的研究成果,对渤海辽东湾海区的海底底形的类型及分布特征进行了系统分析。研究发现,辽东湾海底底形类型丰富,有潮流沙脊、潮流沙席、潮流冲刷槽、古河谷、古湖泊洼地等多种类型。海底底形的发育形态是构造和古地貌、沉积物供给、海平面变化及环境变迁、水动力塑造等多种因素综合作用的结果。     

Influence of shallow gas on the geotechnical properties of pockmark soil: A case study in the East China Sea

Several incidents involving damage to submarine pipelines indicate that there will be potential hazards for many submarine structures if the geotechnical properties of the soil in pockmarks remain unclear. Based on a geophysical survey, geological drilling, in-situ measurement, and shallow gas eruption experiment, two large pockmarks near the Zhongjieshan Archipelago in the East China Sea were analyzed comprehensively. The geophysical and in-situ data indicated that the soil below the two pockmarks contains free or dissolved shallow gas, which continues to migrate upward from the deep zones, but there is no high-pressure gas reservoir in the pockmark soil. In-situ piezocone data, geotechnical results, and shallow gas eruption experiments have demonstrated that the pockmark soil has strengthened mechanical properties and zoning characteristics. After analyzing the pockmark soil in the area where the study was conducted, it was concluded that the pockmark soil in this area is not suitable for the accumulation of high-pressure, shallow gas. It also was concluded that the pockmark soil had stronger mechanical properties than virgin sediment due to the compaction of the soil caused by the eruption of the shallow gas. The zoning characteristics of pockmark soil are due to the regional differences in the ability of shallow gas to carry soil particles, which is a new finding that is worthy of attention in off-shore engineering.     

A pockmark field in the Patras Gulf (Greece) and its activation during the 14/7/93 seismic event

During a recent oceanographical-geophysical survey carried out in the southeastern part of the Gulf of Patras in Western Greece for the construction of an outfall, an active pockmark field was found. The pockmark field was formed in soft layered Holocene silts. The pockmarks are associated with acoustic anomalies attributed to gas-charged sediments. The pockmarks vary in size and shape from 25 to 250 m in diameter and from 0.5 to 15 m in depth and are among the largest and deepest observed in the world.

On July 14th, 1993, during the survey, a major earthquake of magnitude 5.4 on the Richter scale occurred in the area. During the 24 hour period prior to the earthquake the bottom water temperature anomalously increased on three occasions, whilst for a few days after the earthquake it was noted that the majority of the pockmarks were venting gas bublles.

It is considered that the three abrupt sea-water temperature increases were probably the result of upward migrating high-temperature gas bubbles in the water column. It is further suggested that the earthquake was the triggering mechanism and that the gas expulsion was caused by the reduction in the pore volume in the sediments resulting from changes in the stress regime prior to the earthquake. Therefore, it can be suggested that in seismic areas adjacent to pockmark fields, earthquake prediction may be achieved by monitoring the water temperature and/or the rate of gas venting in the pockmark field.

Our analysis indicates that the pockmark field in the Patras Gulf has formed slowly during the Holocene by continuous gas venting, which is periodically being interrupted by short-duration events of enhanced gas seepage triggered by earthquakes.     

The spatial pattern and drainage cell characteristics of a pockmark field,Nile Deep Sea Fan

Over 25,300 seabed pockmarks were mapped from the Rosetta Channel region of the Western Nile Deep Sea Fan (NDSF) using concurrent High Resolution 2D, Chirp profiler and multibeam bathymetry data which spans the Holocene–Pleistocene period. Within the region, a pockmark field containing >13,800 pockmarks was analysed using spatial statistics to determine the distribution of pockmarks within the field. Pockmarks within the field are small (∼16 m diameter), shallow (∼0.5 m deep) circular depressions which formed within the last ∼ 6500 years. The fluid source for the field is identified as an accumulation/generation of gas beneath a hemipelagic seal c. 20–40 ms beneath the seabed. The position of the pockmarks is shown to be unrelated to the depth to the fluid source and an irregular high amplitude acoustic anomaly which is tentatively interpreted as a possible carbonate precipitate of biogenic microbial activity. Statistical spatial analysis of the field confirms the distribution of pockmarks is not random. An exclusion zone surrounding each individual pockmark is identified. The exclusion zone is a unique minimum radius around each pockmark which is not penetrated by any other pockmark. The exclusion zone works in unison with Self-Organised Criticality (SOC) in determining the spatial distribution of pockmarks within the field. The exclusion zone is interpreted as a pockmark “drainage cell”. A conceptual model for a pockmark drainage cell is proposed whereby pockmark formation dissipates a radius/area of fluid and overpressure, thereby preventing the formation of another pockmark within that cell. Consequently, pockmarks are observed to separate or produce anti-clustering tendencies within the field.     

Acoustic evidence of shallow gas accumulations and active pockmarks in the ?zmir Gulf, Aegean sea

Based on high-resolution Chirp seismic, multibeam bathymetry and side scan sonar data collected in the ?zmir Gulf, Aegean Sea in 2008 and 2010, gas-related structures have been identified, which can be classified into three categories: (1) shallow gas accumulations and gas chimneys, (2) mud diapirs, and (3) active and inactive pockmarks. On the Chirp profiles, shallow gas accumulations were observed along the northern coastline of the outer ?zmir Gulf at 3-20 m below the seabed. They appear as acoustic turbidity zones and are interpreted as biogenic gas accumulations produced in organic-rich highstand fan sediments from the Gediz River. The diapiric structures are interpreted as shale or mud diapirs formed under lateral compression due to regional counter-clockwise rotation of Anatolian microplate. Furthermore, the sedimentary structure at the flanks suggests a continuous upward movement of the diapirs. Several pockmarks exist close to fault traces to the east of Hekim Island; most of them were associated with acoustic plumes indicating active degassing during the survey period in 2008. Another Chirp survey was carried out just over these plumes in 2010 to demonstrate if the gas seeps were still active. The surveys indicate that the gas seep is an ongoing process in the gulf. Based on the Chirp data, we proposed that the pockmark formation in the area can be explained by protracted seep model, whereby sediment erosion and re-distribution along pockmark walls result from ongoing (or long lasting) seepage of fluids over long periods of time. The existence of inactive pockmarks in the vicinity, however, implies that gas seepage may eventually cease or that it is periodic. Most of the active pockmarks are located over the fault planes, likely indicating that the gas seepage is controlled by active faulting.     

Formation mechanism of large pockmarks in the subaqueous Yellow River Delta

Abstract

We have identified large pockmarks in an area of approximately 0.3?km² in the subaqueous Yellow River Delta in the Chengdao Sea. Gas eruption channels not been identified in the sediment layers in this area, and the formation mechanism of these large pockmarks remains unknown. To study the formation mechanism of these large pockmarks, we constructed a layered silty sediment model composed of appropriate geological materials. Then, we calculated the stress, displacement, and excess pore pressure in the layered silty sediment from the surface to a depth of 10?m using the Biot theory. A comparative analysis of the calculated results and the data measured in the field was then performed. Based on these results, we established a new formation mechanism for the large pockmarks. With the occurrence of storm waves, two extreme areas of displacement and excess pore pressure appeared in the layered silty sediment. These extreme values increased quickly in the seabed during the continuous action of storm waves. When the excess pore pressure surpassed the effective stress, the top silty layer instantly liquefied and then reconsolidated. Then, when the pore pressure of the interface position exceeded the effective stress produced by the overlying sediment, the sediments experienced “sand boil” damage. With the repeated action of strong waves, the boundary of the pockmark continued to expand, forming a large and stable pockmark. This work is of great value for further understanding and mitigating marine geologic hazards, such as coastal erosion, silt deposition, and unstable sediment, in the subaqueous Yellow River Delta.     

‘Bulls-eye’ pockmarks and polygonal faulting in the Lower Congo Basin: Relative timing and implications for fluid expulsion during shallow burial

This study describes a new type of pockmark association from the Lower Congo Basin offshore West Africa, consisting of up to 8 stacked paleopockmarks separated by intervals of drape and onlap fill. The stacked paleopockmarks occur within the depocentres of polygonally-faulted Plio-Pleistocene sediments and are distributed evenly in the downslope parts of two salt mini-basins. The majority of the stacked pockmarks initiated synchronously in the late Pliocene (~ 3 Ma) with a subordinate initiation phase in the mid Pliocene (~ 4 Ma). The primary agents in pockmark formation are interpreted to be pore water expelled during early-stage compaction together with biogenic methane. Bottom simulating reflections (BSRs) associated with free gas overlain by gas hydrates are currently found in the area. It is speculated that biogenic methane accumulated within and below a clathrate cap, which was repeatedly breached, forming pockmarks at discrete horizons separated by intervals of draping sedimentation. The mid and late Pliocene pockmark initiations appear to coincide with sea-level falls following periods of relatively stable highstand conditions. Several subsequent pockmark horizons may similarly correlate with subsequent sea-level falls during the late Pliocene and early Pleistocene. The stacked paleopockmarks are completely surrounded by polygonal faults and consistently occur within polygonal fault cells that crosscut the succession containing the stacked pockmarks. Early-stage compaction and dewatering of the Pliocene sediments thus preceded polygonal faulting, providing a constraint on the conditions leading to polygonal faulting of the fine-grained host sediments. The relationship documented here is interpreted as due to the presence of a hydrate cap in the Plio-Pleistocene mini-basins which may have retarded the normal compaction processes and facilitated pockmark formation by allowing the build up of gas hydrate and free gas in the basin centres. The relative timing and spatial relationships implies that fluids expelled due to polygonal faulting were not implicated in pockmark formation in this area.     

Linking a linear pockmark train with a buried Palaeozoic structure: a case study from the St. Lawrence Estuary

The 15-km-long Matane pockmark train belongs to a series of NNE-striking alignments of pockmarks mapped on the seafloor of the St. Lawrence Estuary. It includes 109 pockmarks that show a complete transition from well-defined, relatively deep (up to 8.6 m), crater-like depressions to subtle, partly buried morphological features, suggesting that pockmarks have formed at different periods along the whole alignment and that the location of fluid release has changed through time. On seismic profiles, pockmarks are characterized by vertical seismic chimneys that root in the (fractured?) hinge zone of an open anticline within the autochthonous Palaeozoic rocks of the St. Lawrence Platform. In absence of a geochemical characterization of expelled gas, the relationship between the Matane pockmark train and the anticline in a domain characterized by mature source rocks is the strongest evidence for the genetic link between pockmarks and the release of gas from an active hydrocarbon system or a reservoir located in the Palaeozoic succession.

Geophysical exploration of an active pockmark field in the Bay of Concarneau,southern Brittany,and implications for resident suspension feeders

About a decade ago, a large field of pockmarks (individual features up to 30 m in diameter and <2 m deep) was discovered in water depths of 15–40 m in the Bay of Concarneau in southern Brittany along the French Atlantic coast, covering an overall area of 36 km² and characterised by unusually high pockmark densities in places reaching 2,500 per square kilometre. As revealed by geophysical swath and subbottom profile data ground-truthed by sediment cores collected during two campaigns in 2005 and 2009, the confines of the pockmark field show a spectacular spatial association with those of a vast expanse of tube mats formed by a benthic community of the suspension-feeding amphipod Haploops nirae. The present study complements those findings with subbottom chirp profiles, seabed sonar imagery and ultrasonic backscatter data from the water column acquired in April 2011. Results show that pockmark distribution is influenced by the thickness of Holocene deposits covering an Oligocene palaeo-valley system. Two groups of pockmarks were identified: (1) a group of large (>10 m diameter), more widely scattered pockmarks deeply rooted (up to 8 ms two-way travel time, TWTT) in the Holocene palaeo-valley infills, and (2) a group of smaller, more densely spaced pockmarks shallowly rooted (up to 2 ms TWTT) in interfluve deposits. Pockmark pore water analyses revealed high methane concentrations peaking at ca. 400 μl/l at 22 and 30 cm core depth in silty sediments immediately above Haploops-bearing layers. Water column data indicate acoustic plumes above pockmarks, implying ongoing pockmark activity. Pockmark gas and/or fluid expulsion resulting in increased turbidity (resuspension of, amongst others, freshly settled phytoplankton) could at least partly account for the strong spatial association with the phytoplankton-feeding H. nirae in the Bay of Concarneau, exacerbating impacts of anthropogenically induced eutrophication and growing offshore trawling activities. Tidally driven hydraulic pumping in gas-charged pockmarks represents a good candidate as large-scale short-term triggering mechanism of pockmark activation, in addition to episodic regional seismic activity.