塔里木盆地西南地区早中寒武世岩相古地理

塔里木盆地西南地区早中寒武世岩相古地理存在一定争议,这制约了该区的勘探评价。综合利用露头、钻井和地震资料,开展沉积相、地震相分析,并结合区域构造背景,恢复了岩相古地理格局,提出了相应的沉积模式。中下寒武统发育陆棚相、开阔台地相、局限台地相、蒸发台地相和缓坡相。震旦纪末期麦盖提斜坡南部形成水下低隆起,向南在西南坳陷区残留部分被动陆缘,主要发育缓坡相、陆棚相;麦盖提斜坡区地势较高,地层较薄,主要发育局限台地和蒸发台地潮坪;巴楚隆起区水体局限,在干燥炎热气候下形成了厚度较大的蒸发台地膏盐湖沉积。巴楚隆起区和麦盖提斜坡区中下寒武统膏盐岩分布广泛,与下伏碳酸盐岩可构成良好的储盖组合,西南坳陷区残留部分被动陆缘,烃源岩发育条件较好,这表明塔西南具有较好的油气前景。     

一种基于三角分区的广域电离层改正新方法

根据中国地形分布难以建立格网模型的特点,为了解决我国区域电离层精确改正的问题,提出了广域电离层改正三角分区的方法。选择中国地震电离层监测实验网中纬度地区的5个监测站,建立覆盖我国中纬度整个网络服务区域的三角分区电离层模型,并利用8个基准站的数据对该方法的修正精度进行评估,结果表明,对于三角分区内部区域,该方法可以修正到90%左右;对于三角分区外部几百公里以内的区域该方法也能达到80%以上的修正精度,同时利用原始GNSS数据对美国、加拿大等4个IGS跟踪站进行补充实验也验证了该方法的可行性,在保证模型精度的同时较格网法更加简单、有效,对广域电离层延迟误差的修正具有重要的参考价值。     

页岩中气体的超临界等温吸附研究

页岩气等温吸附实验多为临界温度以上的吸附实验,其得到的吸附量为过剩吸附量。为了研究页岩气超临界等温吸附机理,运用重力法,在临界温度以上,分别进行了甲烷和二氧化碳在页岩中的高压等温吸附实验。在分析经典型吸附和超临界吸附区别的基础上,通过修改的超临界等温吸附模型(Langmuir方程和微孔充填(Dubinin Radushkevich,D-R))对实验数据进行了拟合。结果表明:简单的Langmuir方程可近似拟合甲烷吸附实验数据,但精度不高,且无法拟合二氧化碳的吸附数据;将吸附相密度作为可优化参数,修改的微孔充填模型和Langmuir模型能很好地拟合甲烷和二氧化碳的吸附数据,其中修改的微孔充填模型拟合效果最好,且回归得到的超临界甲烷吸附相密度同文献报道的一致,表明吸附气可能以微孔充填的形式存在。      

基于不同高度角的对流层延迟改正模型选择

主要介绍3种对流层延迟改正模型：霍普菲尔德(Hopfield)模型,萨斯塔莫宁(Saastamoinen)模型,勃兰克(Black)模型。根据这三种模型本文利用IGS数据验证了不同高度角的变化对延迟量的影响,并给出了判断三种延迟量优劣的方法,最终提出一种根据高度角不同选择不同模型的综合算法。一定程度上解决了低角度的延迟量误差比较大的问题。     

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5·12汶川地震龙门山风景区地震次生山地灾害特征与处理

5·12汶川地震激发了龙门山风景区崩塌、滑坡、泥石流、堰塞湖等链状次生山地灾害.通过应急调查发现,该区已有堰塞湖5处,危害性崩塌、滑坡6处,已成灾泥石流沟1条,潜在泥石流沟11条,根据各处灾害的主要特征,确定堰塞湖的危险程度,提出山地灾害处理建议.     

山东及周边地块间近期运动状态分析

为研究山东所在块体及周边地块间的地壳相对运动状态,利用2001年以来中国地壳运动观测网络以及2007年以来山东GPS观测网的观测结果,使用K-L最佳直线拟合和滑动傅里叶法得到基线变化年周期,以此对处于不同地块的GPS基准站间基线变化趋势进行分析,得出近期山东内部及周边地块间的地壳运动特征。并利用GPS资料分析了2011年3月11日日本9.0级强震对山东地区的影响。     

Comparison of Two Methods Used to Model Shape Parameters of Pareto Distributions

Two methods are compared for estimating the shape parameters of Pareto field-size (or pool-size) distributions for petroleum resource assessment. Both methods assume mature exploration in which most of the larger fields have been discovered. Both methods use the sizes of larger discovered fields to estimate the numbers and sizes of smaller fields: (1) the tail-truncated method uses a plot of field size versus size rank, and (2) the log–geometric method uses data binned in field-size classes and the ratios of adjacent bin counts. Simulation experiments were conducted using discovered oil and gas pool-size distributions from four petroleum systems in Alberta, Canada and using Pareto distributions generated by Monte Carlo simulation. The estimates of the shape parameters of the Pareto distributions, calculated by both the tail-truncated and log–geometric methods, generally stabilize where discovered pool numbers are greater than 100. However, with fewer than 100 discoveries, these estimates can vary greatly with each new discovery. The estimated shape parameters of the tail-truncated method are more stable and larger than those of the log–geometric method where the number of discovered pools is more than 100. Both methods, however, tend to underestimate the shape parameter. Monte Carlo simulation was also used to create sequences of discovered pool sizes by sampling from a Pareto distribution with a discovery process model using a defined exploration efficiency (in order to show how biased the sampling was in favor of larger fields being discovered first). A higher (more biased) exploration efficiency gives better estimates of the Pareto shape parameters.     

Reviews on Potash Deposit Metallogenic Conditions

Potash salt is one of key scarce strategic resources. Searching for large scale of potash salt deposit is one big problerm which Chinese academic community faces. Many new discoveries of world potash deposit have been made in recent ten years, which provide abundant practical information and complement the potash metallogenic theory. Through the summary of the potash forming characteristics at home and abroad, the paper studies the potash forming time, tectonic condition, paleogeographic condition, paleoclimate, basin location and salt source. Potash is mainly formed in Permian, Cretaceous, late Jurassic, Cambrian and Devonian. The combination of structure and environment helps to form large scale of evaporation. The climate cycle is related with crust activity. As the other ore deposit, the formation of potash ore also needs dry climate. Potash is the product of final stage in brine evolution, and therefore, it needs persistent drought climate. However, the climate condition is very complicated. Drought climate belt also occurs in humid climate stage, which is controlled by geomorphology. Potash ore can also form in local drought condition. Generally, potash forms in rock salt basin. However, the actual situation is very complicated. Some potash basin is coincided with rock salt basin, some is on one side of rock salt basin; and some are even in the outside of rock salt basin. Salt materials can be from three sources: marine source, terrigenous source and deep source.The paper gives an overview of the research status about the potash deposit forming conditions, which has great guiding significance for searching potash deposit in China. The paper also summarizes the three types of metallogenic models for potash deposit, including epicontinental metallogenic model, abnormal marine evaporation model and rift valley model. The three models are mainly different in material sources, in which the potash in epicontinental metallogenic model is from seawater; the potash in abnormal evaporation model is from nonmarine brine and the potash in rift valley model is mainly from deep material of volcanic activity.