Growth behavior and resource potential evaluation of gas hydrate in core fractures in Qilian Mountain permafrost area, Qinghai-Tibet Plateau

The Qilian Mountain permafrost area located in the northern of Qinghai-Tibet Plateau is a favorable place for natural gas hydrate formation and enrichment,due to its well-developed fractures and abundant gas sources.Understanding the formation and distribution of multi-component gas hydrates in fractures is crucial in accurately evaluating the hydrate reservoir resources in this area.The hydrate formation experiments were carried out using the core samples drilled from hydrate-bearing sediments in Qilian Mountain permafrost area and the multi-component gas with similar composition to natural gas hydrates in Qilian Mountain permafrost area.The formation and distribution characteristics of multi-component gas hydrates in core samples were observed in situ by X-ray Computed Tomography(X-CT)under high pressure and low temperature conditions.Results show that hydrates are mainly formed and distributed in the fractures with good connectivity.The ratios of volume of hydrates formed in fractures to the volume of fractures are about 96.8%and 60.67%in two different core samples.This indicates that the fracture surface may act as a favorable reaction site for hydrate formation in core samples.Based on the field geological data and the experimental results,it is preliminarily estimated that the inventory of methane stored in the fractured gas hydrate in Qilian Mountain permafrost area is about 8.67×1013 m3,with a resource abundance of 8.67×108 m3/km2.This study demonstrates the great resource potential of fractured gas hydrate and also provides a new way to further understand the prospect of natural gas hydrate and other oil and gas resources in Qilian Mountain permafrost area.

A natural gas hydrate-oil-gas system in the Qilian Mountain permafrost area, northeast of Qinghai-Tibet Plateau

Natural gas hydrate,oil and gas were all found together in the Qilian Mountain permafrost area,northeast of Qinghai-Tibet Plateau,China.They are closely associated with each other in space,but whether they are in any genetic relations are unknown yet.In this paper,a hydrocarbon gas-generation series,gas-fluid migration series and hydrocarbon gas-accumulation series are analyzed to probe the spatial,temporal and genetic relationships among natural natural gas hydrate,oil and gas.The subsequent results show that natural gas hydrate,oil and gas actually form a natural gas hydrate-oil-gas system.Based on the Middle Jurassic and the Upper Triassic hydrocarbon gas-generation series,it is divided into four major sub-systems in the study area:(1)A conventional Upper Triassic gas-bearing sub-system with peak hydrocarbon gas-generation in the late Middle Jurassic;(2)a conventional Middle Jurassic oil-bearing sub-system with low to mature hydrocarbon gas-generation in the late Middle Jurassic;(3)a natural gas hydrate sub-system with main gas source from the Upper Triassic gas-bearing sub-system and minor gas source from the Middle Jurassic oil-bearing sub-system as well as little gas source from the Middle Jurassic coal-bed gas and the microbial gas;(4)a shallower gas sub-system with microbial alteration of the main gas source from the Upper Triassic gas-bearing sub-system.This natural gas hydrate-oil-gas system and its sub-systems are not only theoretical but also practical,and thus they will play an important role in the further exploration of natural gas hydrate,oil and gas,even other energy resources in the study area.

Gas Hydrates in the Qilian Mountain Permafrost, Qinghai, Northwest China

Qilian Mountain permafrost, with area about 10×10^4 km2, locates in the north of Qinghai- Tibet plateau. It equips with perfect conditions and has great prospecting potential for gas hydrate. The Scientific Drilling Project of Gas Hydrate in Qilian Mountain permafrost, which locates in Juhugeng of Muri Coalfield, Tianjun County, Qinghai Province, has been implemented by China Geological Survey in 2008-2009. Four scientific drilling wells have been completed with a total footage of 2059.13 m. Samples of gas hydrate are collected separately from holes DK-1, DK-2 and DK-3. Gas hydrate is hosted under permafrost zone in the 133-396 m interval. The sample is white crystal and easily burning. Anomaly low temperature has been identified by the infrared camera. The gas hydratebearing cores strongly bubble in the water. Gas-bubble and water-drop are emitted from the hydratebearing cores and then characteristic of honeycombed structure is left. The typical spectrum curve of gas hydrate is detected using Raman spectrometry. Furthermore, the logging profile also indicates high electrical resistivity and sonic velocity. Gas hydrate in Qilian Mountain is characterized by a thinner permafrost zone, shallower buried depth, more complex gas component and coal-bed methane origin etc.

Geochemistry and genesis of authigenic pyrite from gas hydrate accumulation system in the Qilian Mountain permafrost, Qinghai, northwest China

A type of authigenic pyrites that fully fill or semi-fill the rock fractures of drillholes with gas hydrate anomalies are found in the Qilian Mountain permafrost; this type of pyrite is known as "fracture-filling" pyrite. The occurrence of "fracture-filling" pyrite has a certain similarity with that of the hydrate found in this region, and the pyrite is generally concentrated in the lower part of the hydrate layer or the hydrate anomaly layer. The morphology, trace elements, rare earth elements, and sulfur isotope analyses of samples from drillhole DK-6 indicate that the "fracture-filling" pyrites are dominated by cubic ones mainly aligned in a step-like fashion along the surfaces of rock fractures and are associated with a circular structure, lower Co/Ni and Sr/Ba, lower ?REE, higher LREE, significant Eu negative anomalies, and ? 34 SCDT positive bias. In terms of the pyrites' unique crystal morphology and geochemical characteristics and their relationship with the hydrate layers or abnormal layers, they are closely related with the accumulation system of the gas hydrate in the Qilian Mountain permafrost. As climate change is an important factor in affecting the stability of the gas hydrate, formation of fracture-filling pyrites is most likely closely related to the secondary change of the metastable gas hydrate under the regional climate warming. The distribution intensity of these pyrites indicates that when the gas hydrate stability zone(GHSZ) is narrowing, the hydrate decomposition at the bottom of the GHSZ is stronger than that at the top of the GHSZ, whereas the hydrate decomposition within the GHSZ is relatively weak. Thus, the zone between the shallowest and the deepest distribution of the fracture-filling pyrite recorded the largest possible original GHSZ.

Geochemical Characteristics of C_5–C_7 Light Hydrocarbons in Gas Hydrates from the Permafrost Region of Qilian Mountains

As an important part of gas hydrates, light hydrocarbons （LHs）, especially C5 to C7 hydrocarbons with various monomer compounds, provide a wide variety of geological and geochemical information, which have received much attention from organic geochemists and petroleum geologists.

Gas Sources of Natural Gas Hydrates in the Muli Permafrost of Qilian Mountain

The gas hydrates in the permafrost region of Qilian Mountain are characterized by low latitude, thin thickness, shallow burial depth, abundant coal seams, high contents of heavy hydrocarbons and multiple sets of source rocks. Up to date, the source of gas or the main source rocks of the Mull gas hydrates have remained unclear.

Gas Sources for Natural Gas Hydrates in the Permafrost Region of the Qilian Mountains

Objective As a new type of gas hydrates,the natural gas hydrates in the perfost region of the Qilian Mountains are characterized by their shallow burial depth,welldeveloped coal seam,high content of heavy hydrocarbons and multiple sets of mature and over-mature source rocks.Gas sources of these gas hydrates in the study area include coal-type gas and oil-type gas.

天然热释光测量技术在多年冻土区天然气水合物勘查中的应用

冻土区天然气水合物形成机理复杂,成因多源,发展多种捕捉微渗漏信息技术,提高勘查成功率是亟需解决的难题。本文首次把天然热释光测量技术应用于冻土区天然气水合物勘查中,利用RGD-6型热释光剂量仪测试了祁连山冻土区土壤样品热释光强度,总结出适用于木里冻土区天然气水合物勘查的加热程序,以及样品取样粒级。试验结果表明,祁连山冻土区土壤样品最佳取样粒级为-60~100目,最佳升温速率应设置为5℃/s,最佳升温区间为50~400℃。根据祁连山冻土区土壤天然热释光强度异常特征,圈定了天然气水合物在地表的异常边界,天然热释光强度异常模式为顶部异常,与烃类异常模式存在良好的对应关系。土壤天然热释光不受微生物的影响,灵敏度高,是一种很有前景的寻找天然气水合物的方法,在今后的冻土区天然气水合物资源勘查过程中可以将这种技术加以推广。

基于电阻率测井的冻土区水合物储层AMT响应特征研究

音频大地电磁测深(AMT)是以岩石的电性差异为基础来研究地层电性结构的有效探测方法。冻土区水合物具有显著的高阻特征,与围岩存在电性差异,AMT方法可用于冻土区水合物勘探评价。基于祁连山冻土区水合物储层的实际赋存地质特征,结合电阻率测井建立水合物储层的地电模型,采用有限单元法和非线性共轭梯度法数值模拟了AMT方法探测水合物储层的适用范围和最佳采集参数设置方案。当水合物储层孔隙度小于5%、水合物饱和度大于70%、赋存规模小于50 m、埋深超过500 m时,AMT方法难以识别与圈定水合物储层;在水合物可能赋存区域,效果最佳的采集参数为3倍区域宽度的测线长度、11个测点数、4个高频段(100~1000 Hz)的频点数。研究结果可为祁连山冻土区水合物电法勘探提供理论依据和技术支撑。

中国天然气水合物气的成因类型

基于中国祁连山冻土带、南海北部珠江口盆地、台西南盆地的陆坡等天然气水合物样品资料,进行了天然气水合物气的成因类型分析。研究结果表明,祁连山木里地区中侏罗统江仓组发现的天然气水合物气主要是油型气,为自生自储型,δ^(13)C_1值为-52.7‰^-35.8‰,δ^(13)C_2值为-42.3‰^-29.4‰;还发现了少量煤成气,气源岩可能主要为中侏罗统木里组含煤地层,δ^(13)C_1值为-35.7‰^-31.3‰,δ^(13)C_2值为-27.5‰^-25.7‰。南海珠江口盆地与台西南盆地天然气水合物气主要是CO_2还原型生物气,δ^(13)C_1值为-74.3‰^-56.7‰,δD1值为-226‰^-180‰;还发现热成因气遗迹,δ^(13)C_1值为-54.1‰^-46.2‰。综合国内外20个地区(盆地)相关天然气水合物气地球化学资料,提出世界天然气水合物热成因气既有油型气也有煤成气,以油型气为主,在中国祁连山和加拿大温哥华岛附近识别出了少量煤成气,煤成气δ^(13)C_1值重即大于等于-45‰,δ^(13)C_2值大于-28‰;油型气δ^(13)C_1值为-53‰^-35‰,δ^(13)C_2值小于-28.5‰。世界天然气水合物气主要是生物成因气,并以CO_2还原型生物气为主,仅在俄罗斯贝加尔湖盆地发现乙酸发酵型生物气。CO_2还原型生物气δD1值重即大于等于-226‰,乙酸发酵型生物气δD1值轻即小于-294‰。世界天然气水合物的生物气δ^(13)C_1值最重的为-56.7‰,最轻的为-95.5‰,其中-75‰^-60‰是高频段。世界天然气水合物气δ^(13)C_1值最重为-31.3‰,最轻的为-95.5‰;δD_1值最重的为-115‰,最轻的为-305‰。

祁连山冻土区含天然气水合物层段的油气显示现象

以祁连山冻土区天然气水合物钻孔DK-2孔为例,对含油气显示岩心样品进行了储集岩热解分析,结合野外观察到的含油气显示现象,讨论了油气显示性质及其对水合物的可能指示意义。野外观察到的油迹、油斑、油浸、油染等不同级别油气显示现象大多产出在细砂岩、中砂岩中,部分产出在粉砂质泥岩夹薄层碳酸盐岩接触面及裂隙中,它们均得到室内储集岩热解分析结果的证实。油气显示所指示原油性质以中质油、重质油为主,少部分为超重油,甚至为沥青。钻孔中油气显示现象与水合物密切伴生,特别是水合物产出深度段或下部常见具中质油特征的油气显示,或可作为水合物一种指示。

青海祁连山冻土区天然气水合物资源量的估算方法——以钻探区为例

祁连山冻土区天然气水合物DK-1、DK-2、DK-3、DK-4号钻孔揭示,该区天然气水合物及其异常主要产出于破碎岩层裂隙中和砂岩孔隙中,根据不同的赋存类型分别赋予具体地质含义,并运用体积法建立了2种产状天然气水合物资源量的计算方法。基于野外地质观测统计数据和室内分析测试结果,在钻探区约40×104m2的范围内,计算得到砂岩孔隙中的天然气水合物资源量约为6.24×104m3天然气,破碎岩层裂隙中的天然气水合物资源量约为88×104m3天然气,总的资源量约为94.2×104m3天然气。可以看出,钻探区中产于破碎岩层裂隙中的天然气水合物资源量是主体,这与钻探中肉眼观察的结果一致。

祁连山中东部的冻土特征(Ⅰ):多年冻土分布

祁连山地区地势高耸,气候严寒,冰缘现象广布,各类冰缘现象受地形与水分条件的控制,分布具有明显的规律性.祁连山多年冻土属青藏冻土区,阿尔金山-祁连山亚区,分布在海拔3 400 m以上的高山、谷地、盆地中.多年冻土分布具有明显的高度地带性,随高度增加,冻土分布呈现出季节冻土-岛状冻土-连续冻土更替,同时,多年冻土下界高程与经度明显相关,自西向东表现出下降趋势,下降率约为每经度150 m,这一变化与降水在东西方向的变化有关.山区微气候因素复杂多变,也造成了冻土分布的复杂性,局地因素对冻土分布影响显著,对比分析了坡向,植被与水分、岩性,季节性积雪等诸因素对多年冻土分布的影响.

祁连山冻土区天然气水合物DK-8孔岩芯顶空气地球化学特征及其运移指示意义

通过对祁连山木里冻土区天然气水合物DK-8孔不同深度岩芯中气体组分和甲烷碳同位素分析测试,对比分析其变化特征与天然气水合物及异常现象产出层段、断层或破碎带分布之间的空间关系,指出它们对天然气水合物及烃类运移作用的地球化学指示意义。岩芯中气体含量(μL/kg)在149～167m、228～299m、321～338m、360～380m等深度段具异常值特征,它们与天然气水合物及主要异常现象产出层段基本一致,表明岩芯中烃类含量的异常值特征主要是天然气水合物及异常现象的反映。根据离断层或破碎带不同距离岩芯烃类总体积百分比(vol%)、甲烷碳同位素δ13C1值(‰PDB)及C1/C1-5、C1/ΣC2-5、C1/ΣC2-3、C1/C2、C2/C3、C2/ΣC3-4、iC4/nC4、iC5/nC5等特征,代表天然气水合物及其异常的具异常值特征的岩芯中烃类主要由运移而来,它们与断层或破碎带关系密切,下部断层或破碎带是主要烃类运移通道,中上部断层或破碎带可成为天然气水合物赋存空间。

青海祁连山冻土区天然气水合物的气源条件及其指示意义

祁连山木里冻土区天然气水合物的气源条件还不清楚,这直接影响到下一步的勘查方向。文章试图以DK-2天然气水合物钻孔为例,从天然气水合物及其相关气体组成与同位素特征入手,对比分析天然气水合物产出层段的泥岩、油页岩、煤、油气显示等有机地球化学特征,探讨该区天然气水合物的气源条件及其对天然气水合物勘查的指示意义。该区天然气水合物所在层段的泥岩、油页岩、煤的有机质丰度、类型、热演化程度等参数显示,它们不能成为天然气水合物的主要气源岩层;结合天然气水合物及相关气体组成与同位素特征,判断该区天然气水合物的气体来源可能主要为深部石油(原油)伴生气或深部气源岩层的成熟-过成熟气;该区油气显示现象与天然气水合物密切伴生,或可作为天然气水合物的指示标志。

祁连山冻土区天然气水合物分解气碳氢同位素组成特征

开展祁连山冻土区天然气水合物气体同位素研究,是解决其气体成因、来源等科学问题的一个重要手段。本研究采集祁连山南麓多年冻土区水合物科学钻探DK2和DK3孔共8个含水合物的岩芯样品,采用真空顶空法收集样品中水合物的分解气,分别用气相色谱(GC)、气相色谱同位素比值质谱(GC-IRMS)测定其气体成分和同位素组成,测试结果表明:祁连山冻土区天然气水合物样品的气体碳氢同位素变化较大,甲烷、乙烷和丙烷的碳同位素(δ13C)变化范围分别为-52.6‰～-48.1‰、-38.6‰～-30.7‰和-34.7‰～-21.2‰,而二氧化碳的碳同位素(δ13C)最低为-27.9‰,最高为16.7‰;甲烷、乙烷和丙烷的氢同位素(δD)变化范围分别为-285‰～-227‰、-276‰～-236‰和-247‰～-198‰。通过对这些碳氢同位素进行综合研究,包括气体分子组成与同位素的关系分析、甲烷的碳氢同位素之间的关系判断等,结果表明研究区天然气水合物的气体主要来源于热解气,而且是在淡水环境中形成的有机成因气。

祁连山冻土区天然气水合物岩心顶空气组分与同位素的指示意义——以DK-9孔为例

通过对祁连山冻土区天然气水合物DK-9孔不同深度岩心顶空气中的烃类气体组分及甲烷、乙烷的C同位素分析测试,对比分析了岩心顶空气组分含量变化与天然气水合物及其异常层段、油气显示层段、断层或破碎带分布之间的空间关系,探讨了顶空气组分对天然气水合物及其异常现象、油气显示现象、烃类气体运移作用及顶空气同位素对气体成因的指示意义.结果显示,岩心顶空气中烃类气体含量高的深度段180.26-308.50m、356.45-399.32m、458.55-508.65m与天然气水合物及其异常层段、油气显示层段具有较好的对应关系,其高值区间可作为天然气水合物、油气显示的一种指示.距断层或破碎带产出位置不同的岩心顶空气组分含量变化显示,不同级次的断裂系统为烃类气体向上运移提供了通道,部分可为天然气水合物提供一定的赋存空间;甲烷、乙烷C同位素数据显示气体以热解成因为主,部分为混合成因.

青海祁连山冻土区发现天然气水合物

祁连山冻土区位于青藏高原北缘,多年冻土面积约10×104km2,具有良好的天然气水合物形成条件和找矿前景。2008～2009年间中国地质调查局在青海省天峻县木里煤田聚乎更矿区施工"祁连山冻土区天然气水合物科学钻探工程",迄今共完成钻探试验井4口,总进尺2059.13m,分别在DK-1、DK-2和DK-3钻井中钻获天然气水合物实物样品,取得了找矿工作的重大突破。天然气水合物产于冻土层之下,埋深133～396m。水合物呈白色、乳白色晶体,点火能燃烧,红外热像仪测温后呈明显的低温异常,放进水里强烈冒泡,水合物分解后能不断冒出气泡和水滴,并残留下特征的蜂窝状构造。激光拉曼光谱仪检测呈现特征的水合物光谱曲线,测井曲线也具有较明显的高电阻率和高波速标志。祁连山天然气水合物具有冻土层薄、埋深浅、气体组分复杂、以煤层气成因为主等明显特征,是一种新类型水合物。这是我国冻土区首次钻获的天然气水合物实物样品,也是全球首次在中低纬度高山冻土区发现天然气水合物实物样品,具有重要的科学意义和经济意义。

祁连山冻土区天然气水合物烃类气体成因及其意义

对祁连山冻土区天然气水合物钻井岩心游离气样品开展研究，测试烃类气体的组分和碳氢同位素，判断天然气水合物的气体成因类型及成藏模式。结果显示烃类气体组分复杂，除甲烷外，还含有较高的乙烷、丙烷等重烃组分。甲烷碳同位素分布范围最广，气体成因来源相对简单，没有明显受到次生改造作用的影响。该区天然气水合物属于热解成因，判断来自深部的三叠统尕勒得寺组烃源岩。本研究可为我国高原冻土天然气水合物勘探和开发提供理论依据。

青海木里三露天天然气水合物矿藏土壤微量元素地球化学特征

在祁连山冻土区木里天然气水合物矿区进行了微量元素地球化学勘查有效性试验,试验面积150 km2,采样密度2个点/km2。研究表明,土壤Ba、V、Fe、Ca等元素在水合物矿藏上方呈现顶部异常,而且异常吻合程度较高。微量元素预测天然气水合物具有较高的成功率,调查前钻探的干井（DK-4、DK-5和DK-6）位于背景区,调查前钻探的水合物井（DK-1、DK-2、DK-3、DK-7）和调查后水合物井（DK3-11、DK2-13、DK1-14）位于异常内。试验结果还预测了祁连山天然气水合物两个新的远景区。试验表明,微量元素是祁连山冻土区寻找天然气水合物的有效指示元素,它们与水合物其它化探指标结合冻土条件和地质特征综合解释,可以提高冻土区天然气水合物预测成功率。