东太平洋水合物海岭沉积物中黏土矿物与水合物饱和度相关性研究

为了探讨水合物储层中不同黏土矿物与水合物饱和度的关系,选取位于东太平洋水合物海岭国际大洋钻探计划204航次中的3个钻孔(1245B孔、1244C孔和1251B),开展储层沉积物黏土矿物的测试和综合分析。结果表明,蒙脱石、伊利石、绿泥石为主要黏土矿物(平均含量分别为40.3%、33.4%、21.4%);高岭石为次要黏土矿物(平均4.9%)。伊利石、绿泥石、高岭石三种矿物含量的垂向变化规律相似,但它们与蒙脱石的垂向变化趋势相反。该区水合物饱和度与蒙脱石含量呈正相关,且正相关程度在"细粒岩性"层段较高(R=0.55~0.97);水合物饱和度与伊利石、绿泥石、高岭石则显示负相关。3个钻孔中水合物储层厚度、水合物饱和度在各钻孔中分布的差异性表明水合物饱和度的受控因素复杂,首先是气源和流体迁移与供给,其次为沉积物岩性;而"细粒岩性"层段较高含量蒙脱石与水合物饱和度正相关关系可能代表了更次一级的沉积影响因素。为检验其它海区是否也存在黏土矿物对水合物饱和度的影响,将上述3个钻孔与印度外海Krishna-Godavari盆地17-07P钻孔记录进行对比。结果显示,17-07P孔的砂含量高,在粗砂层蒙脱石含量与水合物饱和度呈正相关,反映两个海域岩性对水合物饱和度控制机理不同。上述"细粒岩性"层段蒙脱石含量和伊利石、绿泥石、高岭石3种黏土矿物含量与水合物饱和度之间相关性的差异,可能因为蒙脱石具有特殊层状结构和表面化学性质(层间表面带负电荷、具有可交换的层间水合阳离子等),有利于促进水合物的形成和富集,因而表现为正相关;而伊利石、绿泥石、高岭石自身属性与蒙脱石不同(吸水膨胀能力、对甲烷的吸附能力较蒙脱石弱),不利于水合物的聚集,表现为负相关。

天然气水合物发现区沉积物生气量的模拟实验

为了研究天然气水合物发现区沉积物的CH4生成量,对ODP204航次4个站位(1244,1245,1250和1251)58个沉积物样品进行了5个温度点(25,35,45,55和65℃)的生气量模拟.1244站位的模拟结果显示,气体产物主要为CH4和CO2,未检测到C2+以上的重烃;CH4生成量与模拟温度之间具有很好的相关性,通常在模拟温度35℃时,样品的CH4生成量最大;样品在低温阶段(25和35℃),每克沉积物或有机碳的CH4生成量通常达到最大值.其他3个站位沉积物生气量与1244站位相似.根据4个站位的模拟结果,结合该区的地温梯度,推测海底之下1200m以内的沉积物仍在不断生成生物气,是目前生物成因的天然气水合物的重要气源地;而埋深超过1200m以上的沉积地层已经经过了生物作用大量产气阶段,目前所能产生的生物气的产量已微乎其微,但之前产生的大量生物气对该区水合物成藏贡献很大.而且1200m以上埋深的沉积物开始进入热成因气产气阶段,热解成因气的产生继续为该区水合物提供甲烷来源.

Simulation experiments on gas production from hydrate-bearing sediments

Experiments were made on 58 sediment samples from four sites (1244, 1245, 1250 and 1251) of ODP204 at five temperature points (25, 35, 45, 55 and 65°C) to simulate methane production from hydrate-bearing sediments. Simulation results from site 1244 show that the gas components consist mainly of methane and carbon dioxide, and heavy hydrocarbons more than C2 + cannot be detected. This site also gives results, similar to those from the other three, that the methane production is controlled by experimental temperatures, generally reaching the maximum gas yields per gram sediment or TOC under lower temperatures (25 and 35°C). In other words, the methane amount could be related to the buried depth of sediments, given the close relation between the depth and temperature. Sediments less than 1200 m below seafloor are inferred to still act as a biogenic gas producer to pour methane into the present hydrate zone, while sedimentary layers more than 1200 m below seafloor have become too biogenically exhausted to offer any biogas, but instead they produce thermogenic gas to give additional supply to the hydrate formation in the study area.