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本文根据杭州湾沿海平原大量的钻井、静力触探井和分析化验等资料,研究了下切河谷(钱塘江和太湖下切河谷)充填物的沉积建造和沉积相,以及浅层生物气藏分布特征。研究表明,末次冰期以来,随着海平面变化,杭州湾地区下切河谷演化经历了深切、快速充填和埋藏三个阶段。末次冰盛期,海平面下降的幅度大,增加了河流梯度、加强了下切作用,本区形成了钱塘江和太湖下切河谷,随后在冰后期被充填和埋藏,下切河谷的两侧为暴露地表的古河间地。根据岩石学、沉积结构和沉积构造特征,本区下切河谷充填沉积物表现为向上变细的沉积层序,可以划分为4个沉积相类型,有河床滞留沉积物到部分曲流河沉积体系的边滩沉积、河漫滩-河口湾沉积、河口湾-浅海沉积和河口湾沙坝沉积。在河漫滩-河口湾相沉积期间,由于海平面上升、潮流体系、沉积物供给和可容空间条件适合一个潮流沙脊体系的发育,该相中砂质透镜体可能代表下切河谷内发育的潮流沙脊。对于河口湾-浅海沉积和河口湾沙坝沉积而言,由于沉积条件不再有利,没有形成沙脊沉积。所有的商业性生物气都存储在下切河谷内河漫滩-河口湾砂质透镜体中。 相似文献
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依据对江苏省泰兴市黄桥镇钻孔和海门市钻孔、上海长兴岛钻孔地层岩心沉积特征的研究,讨论
了冰后期以来长江三角洲河口地区的层序地层。研究表明,沿古河谷纵剖面各河段地层中沉积相组合关系有明
显区别。在古河谷下端地区,下切河谷充填层序自下而上由河流相、河口湾相、浅海相和三角洲相组成,沉积
相组合最完整。在古河谷上端地区,由于河口湾在海侵发生时存在着涌潮作用,因此,河漫滩泥质沉积层顶部
的冲刷面被确定为最大海泛面,其上覆稳定的河口砂体;浅海相和河口湾相沉积在该区域变薄直至尖灭;层序
顶部由中潮坪突变为高潮坪,最终形成泛滥平原。这意味着,原先确定的自西向东的长江三角洲的几个亚三角
洲或河口砂体沉积,并非都具有向上变粗的三角洲层序。文中报道的3个钻孔,揭露了冰后期长江三角洲完整
的下切河谷充填层序。河口湾顶不具备三角洲层序的地区应称为滨海平原。 相似文献
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应用800多口钻孔及文献资料,讨论了中国沿海滦河扇三角洲、长江三角洲和珠江三角洲及钱塘江河口湾4个地区的下切河谷体系,这些皆为丰沙河流形成的河口三角洲。这些河口三角洲地区的下切河谷为长形或扇形,长数十至数百千米,宽数十千米,深40~90 m。河口三角洲地区的下切河谷相序可分为4种类型,即FS-Ⅰ,FS-Ⅱ,FS-Ⅲ和FS-Ⅵ。可以将这4类相序自海向陆排成一个理想序列:FS-Ⅰ位于海岸线附近,FS-Ⅳ位于河口三角洲的顶部,显示海的影响逐渐减弱,陆相作用逐渐增强。下切河谷层序可分为海侵和海退序列。海侵序列的厚度占下切河谷层序的50%以上,体积占60%~70%。海侵序列是在海平面上升过程中,溯源堆积依次叠置而成的,其下部的河床相是在溯源堆积能到达、而涨潮流未能到达的下游河段产生的,往往不含海相微体化石和潮汐沉积构造。在海侵序列中未见区域上可对比的侵蚀面,表明冰后期海平面上升速率的变化、甚至小幅下降也未留下统一的侵蚀记录。下切河谷中的海退序列由河口湾充填及三角洲进积而成,其进程是各不相同的:长江古河口湾先被强潮河口湾相、后由三角洲相所充填,河口湾也经历了由强潮型向中潮型的转变;滦河扇三角洲和珠江三角洲,其古河口湾则被河流相和三角洲相所充填;钱塘江河口湾正被强潮河口湾相所充填。 相似文献
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对长江三角洲晚第四纪地层沉积特征进行了精细研究,探讨了研究区层序地层格架,在此基础上分析了浅层生物气成藏条件、特征和分布规律。研究表明,长江三角洲晚第四纪发育3期下切河谷,形成了3套沉积层序;因后期河流的强烈下切破坏,早期沉积层序往往被剥蚀殆尽,仅残留下部的河床相粗粒沉积,造成不同期河床相的叠置;相对而言,末次冰期以来形成的下切河谷沉积层序以相对完整的沉积相组合被保存下来。长江三角洲浅层天然气是未经运移的原生生物气,其主要富集于末次冰期以来的沉积层序内,气藏为自生自储同生型的岩性圈闭。河口湾—河漫滩和浅海相泥质沉积物既是气源岩,又是盖层,后者可作为良好的区域盖层;河口湾—河漫滩和河床相砂质沉积物为主要储集层。因此,研究区晚第四纪多期下切河谷沉积层序有利于浅层生物气藏的形成,特别是晚期下切河谷内河口湾—河漫滩相砂质透镜体以及河床相砂体可作为优先勘探目标。 相似文献
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鄂尔多斯西缘前陆盆地上古生界沉积相特征研究 总被引:3,自引:0,他引:3
在层序地层学研究的基础上,对鄂尔多斯盆地西缘逆冲构造带上古生界进行了详细的沉积相研究.分析出该地发育了6种沉积相,分别为碳酸盐潮坪相、障壁砂坝-泻湖相、河口湾相、三角洲相、河流相、湖泊相.并按上古生界识别出的2个二级层序,推测出沉积相的平面展布特征,总结出鄂尔多斯盆地西缘地区,晚古生代沉积演化经历了拗拉槽再活动背景下的裂谷海湾充填、陆表海充填和内陆坳陷充填3个发展阶段.并结合构造、物源供给、海侵、古气候等条件分析了鄂尔多斯西缘前陆盆地上古生界沉积相演化的控制因素. 相似文献
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下切河谷的研究不仅可以正确划分地层、确立年代地层格架、判定沉积环境演变、探讨海平面变化规律,对碳氢化合物勘探开发、地质工程等重大国民经济建设也有重要意义。本文介绍了下切河谷体系概念、特征、划分类型、研究历程和科学意义,着重论述了晚第四纪下切河谷的形成演化、层序地层格架和控制因素。晚第四纪下切河谷体系主要是海平面下降、河流向盆地扩展并侵蚀下伏地层的下切河流体系,在海平面上升时期被充填的长条状负向地形,以区域性的地层不整合面为底界。浪控型与潮控型下切河谷体系模式有许多不同之处:① 前者存在河口砂坝、中央盆地、湾顶三角洲,后者则没有这些沉积单元;② 前者浅海沉积较薄,后者较厚;③ 前者代表了贫砂的小河河口湾,由于泥砂量少,河口湾在最大海侵线附近,后者河流作用较强,泥砂量相对大,现代河口湾不断向海扩展,较下切河谷范围要大的多;④ 前者涉及溯源堆积在下切河谷充填中的作用,但对其强度估计不足。下切河谷体系的形成演化的影响因素众多,海平面变化、沉积物供应、沉积过程、下切河谷形态和气候变化等是主要控制因素。 相似文献
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贵州西部龙潭组主要含有6种沉积相组合:即浅海沉积、细粒滨岸平原沉积、溢岸沉积、小型河道砂体、叠置河道砂体和煤层。多层叠置砂体一般10-25m厚,2-10km宽,常含海绿石,切入下伏的三角洲平原、滨岸平原和浅海沉积中,被认为是下切谷充填。在龙潭组中共识别出广泛发育的10个层序界面,由此所限定的层序大致相当于4级旋回层序。在这些层序中,准层序或准层序组识别不出,然能识别体系域,层序几乎全由海进体系域(TST)和高位体系域(HST)组成,低位体系域(LST)发育不好。在垂向上,它们又可叠置成3级复合层序,并由低位、海进和高位层序组组成。在低位层序组中,河道下切常冲刷掉下伏层序的全部HST和部分TST,致使其与下伏层序的下切谷充填重合。在海进层序组中,下切作用最弱,具最小砂/泥比值,下切谷充填侧向孤立。高位层序组是低位和海进层序的过渡类型,下切谷充填也趋于孤立。 相似文献
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江苏南通地区晚第四纪下切河谷沉积与环境演变 总被引:1,自引:0,他引:1
采用层序地层学基本原理,以海平面升降旋回为主线,根据钻井岩芯、古生物、测年和分析化验等资料,探讨了江苏南通地区晚第四纪地层层序、层序界面、沉积特征及沉积环境的演变。结果表明,研究区晚第四纪发育三期下切河谷,形成了三套沉积层序,自下而上三个层序的地质时代分别相当于晚第四纪早期、晚第四纪中期和晚第四纪晚期。由于后期河流的强烈下切破坏,早期沉积层序往往被剥蚀殆尽,仅残留下部的河床相粗粒沉积,造成不同期河床相的叠置;相对而言,晚第四纪晚期形成的下切河谷沉积层序以不同的沉积相组合被保存下来,自下而上划分为河床、河漫滩、河口湾、浅海和三角洲5种沉积相类型,表现为一个较完整的沉积层序。晚第四纪晚期下切河谷底界面,是末次冰期海面下降,河流下切形成的侵蚀面,与河间地古土壤层顶面的沉积间断面同属一个地史期的产物,一起构成区域不整合面,界面上下岩性突变,其上的冰后期地层属同一个海平面变化旋回,可互相对比,因而具有年代地层学意义。三期下切河谷层序的套叠结构表明,晚第四纪以来,研究区存在三次"低海面-海侵-高海面-海退"周期性海面变化。 相似文献
10.
在前人研究基础上,通过钻井岩心描述和测井曲线对比,根据岩石学特征、沉积相标志、测井相标志等对加拿大Athabasca地区下白垩统McMurray组进行了沉积特征分析。McMurray组主要发育了河流相、三角洲相和滨海沉积,总体呈海平面相对上升变化。纵向上,中下部层序以河流相为主,沉积物多为来自盆地周边的近物源,以西部物源为主。短河流汇入盆地后可沿盆地长轴南北发育,成为北部区块的长物源。上部层序受西北方向海侵的影响,自北向南发育滨海-河口湾-三角洲相沉积。 相似文献
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The upper Hawkesbury River, New South Wales, Australia: a Holocene example of an estuarine bayhead delta 总被引:1,自引:0,他引:1
Holocene deposits of the Hawkesbury River estuary, located immediately north of Sydney on the New South Wales coast, record the complex interplay between sediment supply and relative sea-level rise within a deeply incised bedrock-confined valley system. The present day Hawkesbury River is interpreted as a wave-dominated estuarine complex, divisible into two broad facies zones: (i) an outer marine-dominated zone extending 6 km upstream from the estuary mouth that is characterized by a large, subtidal sandy flood-tidal delta. Ocean wave energy is partially dissipated by this flood-tidal delta, so that tidal level fluctuations are the predominant marine mechanism operating further landward; (ii) a river-dominated zone that is 103 km long and characterized by a well developed progradational bayhead delta that includes distributary channels, levees, and overbank deposits. This reach of the Hawkesbury River undergoes minor tidal level fluctuations and low fluvial runoff during baseflow conditions, but experiences strong flood flows during major runoff events. Fluvial deposits of the Hawkesbury River occur upstream of this zone. The focus of this paper is the Hawkesbury River bayhead delta. History of deposition within this delta over the last c. 12 ka is interpreted from six continuous cores located along the upper reaches of the Hawkesbury River. Detailed sedimentological analysis of facies, whole-core X-ray analysis of burrow traces and a chronostratigraphic framework derived from 10 C-14 dates reveal four stages of incised-valley infilling in the study area: (1) before 17 ka BP, a 0–1 m thick deposit of coarse-grained fluvial sand and silt was laid down under falling-to-lowstand sea level conditions; (2) from 17 to 6·5 ka BP, a 5–10 m thick deposit composed of fine-grained fluvial sand and silt, muddy bayhead delta and muddy central-basin deposits developed as the incised valley was flooded during eustatic sea-level rise; (3) during early highstand, between 6·5 and 3 ka BP, a 3–8 m thick bed of interbedded muddy central-basin deposits and sandy river flood deposits, formed in association with maximum flooding and progradation of sandy distributary mouth-bar deposits commenced; (4) since 3 ka BP, fluvial deposits have prograded toward the estuary mouth in distributary mouth-bar, interdistributary-bay and bayhead-delta plain environments to produce a 5–15 m thick progradational to aggradational bayhead-delta deposit. At the mouth of the Hawkesbury estuary subaqueous fluvial sands interfinger with and overlie marine sands. The Hawkesbury River bayhead-delta depositional succession provides an example of the potential for significant variation of facies within the estuarine to fluvial segment of incised-valley systems. 相似文献
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Sedimentological and ichnological implications of rapid Holocene flooding of a gently sloping mud‐dominated incised valley – an example from the Red River (Gulf of Tonkin) 
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下载免费PDF全文 Andreas Wetzel Agata Szczygielski Daniel Unverricht Karl Stattegger 《Sedimentology》2017,64(5):1173-1202
The Gulf of Tonkin coastline migrated at an average rate of ca 60 m year?1 landward during Holocene sea‐level rise (20 to 8 ka). Due to a combination of rapid coastline migration and undersupply of sand, neither coastal barriers nor tidal sand bars developed at the mouth of the Red River incised valley. Only a 30 to 80 cm thick sandy interval formed at the base of full‐marine deposits. Thus, the river mouth represented a mud‐dominated open funnel‐shaped estuary during transgression. At the base of the valley fill, a thin fluvial lag deposit marks a period of lowered sea‐level when the river did not reach geomorphic equilibrium and was thus prone to erosion. The onset of base‐level rise is documented by non‐bioturbated to sparsely bioturbated mud that occasionally contains pyrite indicating short‐term seawater incursions. Siderite in overlying deposits points to low‐salinity estuarine conditions. The open funnel‐shaped river mouth favoured upstream incursion of seawater that varied inversely to the seasonal strongly fluctuating discharge: several centimetres to a few tens of centimetres thick intervals showing marine or freshwater dominance alternate, as indicated by bioturbational and physical sedimentary structures, and by the presence of Fe sulphides or siderite, respectively. Recurrent short‐term seawater incursions stressed the burrowing fauna. The degree of bioturbation increases upward corresponding to increasing marine influence. The uppermost estuarine sediments are completely bioturbated. The estuarine deposits aggraded on average rapidly, up to several metres kyr?1. Siphonichnidal burrows produced by bivalves, however, document recurrent episodes of enhanced deposition (>0·5 m) and pronounced erosion (<1 m) that are otherwise not recorded. The slope of the incised valley affected the sedimentary facies. In steep valley segments, the marine transgressive surface (equivalent to the onset of full‐marine conditions) is accentuated by the Glossifungites ichnofacies, whereas in gently sloped valley segments the marine transgressive surface is gradational and bioturbated. Marine deposits are completely bioturbated. 相似文献
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The evolution of incised valleys is an important area of research due to the invaluable data it provides on sea‐level variations and depositional environments. In this article the sedimentary evolution of the Ría de Ferrol (north‐west Spain) from the Last Glacial Maximum to the present is reconstructed using a multidisciplinary approach, combining seismic and sedimentary facies, and supported by radiocarbon data and geochemical proxies to distinguish the elements of sedimentary architecture within the ria infill. The main objectives are: (i) to analyse the ria environment as a type of incised valley to evaluate the response of the system to the different drivers; (ii) to investigate the major controlling factors; and (iii) to explore the differentiation between rias and estuaries. As a consequence of the sea‐level rise subsequent to the Last Glacial Maximum (ca 20 kyr bp ), an extensive basin, drained by a braided palaeoriver, evolved into a tide‐dominated estuary and finally into a ria environment. Late Pleistocene and Holocene high‐frequency sea‐level variations were major factors that modulated the type of depositional environments and their evolution. Another major modulating factor was the antecedent morphology of the ria, with a rock‐incised narrow channel in the middle of the basin (the Ferrol Strait), which influenced the evolution of the ria as it became flooded during Holocene transgression. The strait acted as a rock‐bounded ‘tidal inlet’ enhancing the tidal erosion and deposition at both ends, i.e. with an ebb‐tidal delta in the outer sector and tidal sandbanks in the inner sector. The final step in the evolution of the incised valley into the modern‐defined ria system was driven by the last relative sea‐level rise (after 4 kyr bp ) when the river mouths retreated landward and a single palaeoriver was converted into minor rivers and streams with scattered mouths in an extensive coastal area. 相似文献
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Sedimentation in a river dominated estuary 总被引:2,自引:0,他引:2
J. ANDREW G. COOPER 《Sedimentology》1993,40(5):979-1017
The Mgeni Estuary on the wave dominated east coast of South Africa occupies a narrow, bedrock confined, alluvial valley and is partially blocked at the coast by an elongate sandy barrier. Fluvial sediment extends to the barrier and marine deposition is restricted to a small flood tidal delta. Sequential aerial photography, sediment sampling and topographical surveys reveal a cyclical pattern of sedimentation that is mediated by severe fluvial floods which exceed normal energy thresholds. During severe floods (up to 10x 103 m3 s?1), lateral channel confinement promotes vertical erosion ofbed material. Eroded material is deposited as an ephemeral delta in the sea. After floods the river gradient is restored within a few months through rapid fluvial deposition and formation of a shallow, braided channel. Over an extended period (approximately 70 years) the estuary banks and bars are stabilised by vegetation and mud deposition. Subsequent downcutting in marginal areas transforms the channel to an anastomosing pattern which represents a stable morphology which adjusts to the normal range of hydrodynamic conditions. This cyclical pattern of deposition produces multiple fill sequences in such estuaries under conditions of stable sea level. The barrier and adjacent coastline prograde temporarily after major floods as the eroded barrier is reformed by wave action, but excess sediment is ultimately eroded as waves adjust the barrier to an equilibrium plan form morphology. Deltaic progradation is prevented by a steep nearshore slope, and rapid sediment dispersal by wave action and shelf currents. During transgression, estuarine sedimentation patterns are controlled by the balance between sedimentation rates and receiving basin volume. If fluvial sedimentation keeps pace with the volume increase of a basin an estuary may remain shallow and river dominated throughout its evolution and excess fluvial sediments pass through the estuary into the sea. Only if the rate of volume increase of the drowned river valley exceeds the volume of sediment supply are deep water environments formed. Under such conditions an estuary becomes a sediment sink and infills by deltaic progradation and lateral accretion as predicted by evolutionary models for microtidal estuaries. Bedrock valley geometry may exert an important control on this rate of volume increase independently of variations in the rate of relative sea level change. If estuarine morphology is viewed as a function of the balance of wave, tidal and fluvial processes, the Mgeni Estuary may be defined as a river dominated estuary in which deltaic progradation at the coast is limited by high wave energy. It is broadly representative of other river dominated estuaries along the Natal coast and a conceptual regional depositional model is proposed. Refinement of a globally applicable model will require further comparative studies of river dominated estuaries in this and other settings, but it is proposed that river dominated estuaries represent a distinct type of estuarine morphology. 相似文献
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Dilce F. Rossetti Antnio E. Santos Júnior 《Journal of South American Earth Sciences》2004,17(4):1032
The Miocene Barreiras Formation in the Middle Rio Capim area records an incised valley system for which facies analysis and ichnology (Skolithos, Ophiomorpha, Planolites, Gyrolithes, Taenidium) suggest an estuarine character. Three stratigraphic units are recognized (from bottom to top): Unit 1 includes an inner estuarine tidal channel complex and tidal flat/salt marsh deposits; Unit 2 consists of estuarine bay/lagoon and flood tidal delta deposits related to the estuary mouth; and Unit 3 includes a tidal channel with a tidal point bar, as well as tidal flat/salt marsh deposits similar to those from Unit 1. These units and their bounding surfaces record the history of relative sea level changes in the estuary. After a sea level drop, the valley was inundated and formed an amalgamated sequence boundary and transgressive surface. Transgression (Unit 1) promoted the landward shift of flood tidal deltas and lagoon settings (Unit 2). The system then moved seaward, with the superposition of inner estuarine deposits (Unit 3) over Unit 2. Facies architecture seems to have been controlled by tectonics, as shown by: the paleovalley orientation according to the main tectonic structures of the basin; the presence of faults and fractures that displace the basal unconformity; and the abundance of soft sediment deformation. 相似文献
17.
东濮凹陷沙河街组河口湾环境发育的最初征兆是出现震积岩(Seismites)和水下脱水收缩裂隙(Synaeresis),预示其基底有构造性下沉,海水在间歇性地灌入,接着淡水介形类开始大量死亡。与海水有关的生物痕迹如Ophiomorpha、Tigillites屡屡出现,说明此时此地淡水水体已被河口湾咸水水体所取代,最后剖面中见到滨海高能环境下的生物痕迹Arenicolites和鲕粒砂岩、介壳碎屑层等,指示潮道和潮汐坝的存在。至此,这一地区的河口湾以陆相(分流河道)-陆海混合相(河口湾点坝)-海相(潮道)为代表的三元结构,便完整地记录了一次海面升降周期。由陆相动物活动痕迹、植物活动痕迹和古土壤识别出的陆相部分在沙河街组有10层(开31井),由海相生物痕迹、海相生物及海相内源沉积物识别出的海相部分有12层(开31井、新胡4井),说明沙河街组沉积期曾有过10次以上的海面升降过程。海面下降时,河流沿兰聊断裂和内黄凸起间断裂谷地侵蚀切割两岸形成可容空间;海面上升期,此可容空间部分或全部被不同类型的沉积物所充填,形成了分流河道、河口湾点坝砂为代表的下切谷型储层和以潮道、滩坝砂体为代表的超覆型储层。 相似文献
18.
近年来,在浙江省北部钱塘江河口湾地区发现并开发了大量的晚第四纪浅层生物气藏。末次盛冰期,全球海平面的下降使河流梯度增加,下切作用增强,导致钱塘江下切河谷的形成。下切河谷内的沉积序列从下到上可划分为4种沉积相类型,分别为河床相、河漫滩-河口湾相、河口湾-浅海相和河口湾砂坝相。 所有的商业浅气田和气藏都分布于太湖下切河谷和钱塘江下切河谷及其支谷的河漫滩-河口湾相砂体中。钱塘江下切河谷的河漫滩-河口湾砂体埋深30~80 m,厚3~7 m,被非渗透的黏土包围,可能代表了下切河谷内分布的潮流沙脊。快速堆积的河口湾-浅海相沉积物为生物气藏的形成提供了充足的源岩和良好的保存条件。 河漫滩-河口湾相的黏土层为研究区浅层生物气藏的直接盖层,主要分布在下切河谷内,其埋深、残留地层厚度和孔隙度范围分别为30~80 m、10~30 m和42.2%~62.6%。河口湾-浅海相的淤泥层为间接盖层,覆盖了整个下切河谷,其埋深、残留地层厚度和孔隙度范围分别为5~35 m、10~20 m和50.6% ~53.9%。黏土层和淤泥层的孔隙水压力远大于下伏砂体的孔隙水压力,其差值可达0.48 MPa。在储集层和盖层分界面即浅气藏的顶部,孔隙水压力值达到最大。黏土层和淤泥层的孔隙水压力可以超过砂质储集层中气体压力和孔隙水压力之和。黏土和淤泥盖层的高孔隙水压力可能是浅层生物气被完全封闭住的最重要因素。直接盖层的封闭能力比间接盖层要好。黏土层和淤泥层的孔隙水压力消散时间很长,有时候很难达到稳定状态,这表明黏土层和淤泥层的渗透性差、封闭性好。随着埋深的增加,其压实程度和封闭性能增加。与黏土层和淤泥层相比,砂层的孔隙水压力消散较快,很容易达到稳定状态,而且消散时间与埋深无关,表明砂层渗透性好、封闭性差。气体一旦进入砂层,孔隙水就不能有效释放,导致砂层的孔隙水压力消散时间比黏土层和淤泥层的要长,这可能与生物气在孔隙水压力释放后的快速补充有关。 相似文献