冈底斯地区林子宗群火山岩岩石地球化学特征及地球动力学意义

错卧莫-惩香错火山-沉积盆地位于西藏冈底斯陆块中部南缘。盆地内火山-沉积地层称古新世-渐新世林子宗群，岩石地球化学数据分析表明：这套火山岩系属钙碱性系列，轻稀土富集，不同程度表现出负Eu、负Ce、负Nb异常。微量元素K、Rb、Th、Ce富集，Sr、Ba，尤其是Nb、P、Ti亏损。初步认为这套火山-沉积岩系形成于俯冲造弧的构造背景中，是来自于俯冲带的地幔源区基性分异岩浆与陆壳重熔的酸性岩浆在不同的时间段内，按不同的比例混合形成的。同时，俯冲板块上深海沉积物与基性岩浆混合作用也是不容忽视的因素。在综合分析基础上，笔者认为印度板块与欧亚板块的碰撞启动时间在45Ma以后。     

西藏马攸木金矿床流体物理化学条件初步研究

据研究,西藏马攸木金矿床的成矿作用主要发生在中-低温(140～311℃)、低盐度(<11.4%)、浅成(压力<35.46 MPa)、弱酸性(pH＝4.566～4.750)和还原环境下(Eh＝-0.782～0.232).通过对该矿床物理化学条件的研究,表明马攸木金矿床在成因上属浅成中低温热液矿床.     

极不充分采动条件下地表下沉规律及计算方法研究

随着煤矿开采的不断加深,地表呆动程度(开采宽度D与开采深度H之比DIH)不断降低,并逐渐趋向于极不充分采动,同样长度的工作面对地表的影响程度极不同于浅部开采。因此,需要重新认识深部开采时的地表下沉规律。极不充分采动条件下地表下沉规律具有特殊性。经过对国内外大量观测资料的综合分析,发现当开采宽度小于地表下沉起动距时(极不充分采动),地表的下沉或地表下沉率(q′／q)为零。当开采宽度达到地表移动起动距时,地表下沉缓慢增长;达到临界采动距时,地表下沉急剧增大。地表下沉率(q′／q)与开采宽、深比D／H之间为负指数函数关系。在极不充分采动条件下进行地表下沉预计时必须对概率积分法的下沉系数进行修正。算例证明了本文给出计算方法的可行性。但这种修正方法如何与概率积分法相统一仍需进一步研究。     

滇东南老君山矿集区北部长田W(Sn)矿床成矿时代：来自白钨矿和萤石 Sm- Nd同位素定年的制约

滇东南是我国重要的钨锡多金属成矿区,老君山矿集区是其重要组成部分,围绕燕山期老君山复式花岗岩体,分布有都龙、南秧田、新寨大型-超大型Sn-W多金属矿床及多个中小型矿床(点)。该区地质演化复杂,Sn、W多金属可能存在多期成矿作用,包括燕山期、印支期和加里东期。由于目前该区发现的Sn-W矿化多分布于老君山岩体南、东侧,而岩体北部Sn-W成矿作用的研究相对较薄弱,特别是成矿年代学方面,多数矿床依然缺少精确同位素年代学数据,制约了该区Sn-W多金属成矿作用的认识和地质勘探的深入。长田是老君山岩体北缘代表性W (Sn)多金属矿床,区内加里东期和燕山期花岗岩均有分布,由于缺少年代学数据和地质地球化学研究,W(Sn)成矿作用的认识尚缺少实际地质地球化学依据,难以建立合理的成矿模式,制约了区内地质勘探的深入和突破。基于此,本文通过对长田W (Sn)矿床中白钨矿及共生萤石的Sm-Nd同位素定年,分别获得97 Ma和79 Ma两个年代学数据,显示该矿床钨矿化主成矿期应为燕山晚期,与老君山花岗岩活动时限一致,表明长田钨成矿作用与燕山期老君山花岗岩的侵入活动关系密切,而与加里东期岩浆活动关系不大。该成果丰富了...     

东非鲁武马盆地始新统超深水重力流砂岩储层特征及成因

鲁武马盆地古近系-新近系发育多套超深水、超大型、富含天然气藏的重力流沉积砂体。以始新统砂体为解剖对象,分析区内重力流砂岩储层特征及成因。结果表明砂体以巨厚层状产出于深海泥岩内部,并与周围泥岩截然接触,测井曲线表现出宏观均一性;岩心揭示此类巨厚砂体是由多期单砂体叠置而成,单砂体是由底部高密度颗粒流和顶部低密度浊流两部分组成,且经历过强底流改造。鲁武马河流三角洲强大物源供给决定了区内砂体分布面积和体积规模;深海滑塌、块体搬运等重力流沉积过程控制了沉积体粒序构造和内部结构;海底区域性强底流持续冲刷并携带走单砂体顶部细粒沉积物,残留了底部“干净”的中粗粒砂岩;多期沉积事件和频繁水道迁移决定了砂体纵、横向叠加展布,并最终形成了区内厚度巨大、岩性宏观均一且连通性极好的超大型深水重力流沉积砂岩储层。     

江南造山带黄金洞金矿床成矿机制:矿物形成环境与金成矿物理化学条件制约

黄金洞超大型金矿床位于江南造山带中段,赋存于新元古界浅变质岩系中,受控于NNE-NE向长平断裂带,金资源储量达100吨。该矿床可由南至北分为金福、金塘、杨山庄和曲溪矿段,主要矿化类型有石英-硫化物脉型、构造角砾岩型和黄铁毒砂绢英岩型。金属矿物主要发育有自然金、毒砂、黄铁矿、黄铜矿、闪锌矿、方铅矿、磁黄铁矿等;非金属矿物有石英、绢云母、方解石和菱铁矿等,其中金主要以自然金与不可见金形式存在。根据野外与镜下观察,金成矿作用分为Ⅰ石英-金-毒砂-黄铁矿、Ⅱ石英-金-多金属硫化物-白钨矿和Ⅲ石英-辉锑矿-绿泥石3个阶段,前二者为主要成矿阶段。曲溪矿段Ⅱ阶段毒砂相对不发育、而磁黄铁矿和自然金显著发育,绿泥石主要发育于Ⅲ阶段中,与辉锑矿及闪锌矿共生。根据不同矿段各阶段毒砂与Ⅲ阶段绿泥石成分,计算其温度、lgf(S_2)与lgf(O_2),可见Ⅰ阶段成矿温度与硫逸度高于Ⅱ阶段:杨山庄矿段两阶段成矿温度分别为300～378℃、260～300℃,lgf(S_2)分别为-11～-7.2、-11.9～-10.1;金塘两阶段成矿温度为240～311℃、245～298℃;金福Ⅱ阶段成矿温度上限为297℃;曲溪矿段成矿温度为268～368℃,Ⅱ阶段毒砂lgf(S_2)与Ⅲ阶段绿泥石lgf(O_2)分别为-13.2～-8.7、-50.9～-40.1。根据不同阶段矿物之间的相互关系及成矿温度与硫逸度演化特征,推断Ⅰ、Ⅱ成矿阶段伴随强烈的硫化作用,金以类质同象方式进入毒砂和黄铁矿中,形成不可见金;其中Ⅱ阶段由于成矿流体压力骤降,含金流体发生相分离作用,H2S等气体大量逃逸,导致成矿流体中硫含量骤降,加以硫化作用持续消耗流体中的硫,促进了含金络合物分解与自然金的沉淀。     

Control Factors and Diversities of Phase State of Oil and Gas Pools in the Kuqa Petroleum System

Based on the analysis of the hydrocarbon geochemical characteristics in the Kuqa petroleum system of the Tarim Basin, this study discusses the causes and controlling factors of the phase diversities and their differences in geochemical features. According to the characteristics and differences in oil and gas phase, the petroleum system can be divided into five categories: oil reservoir, wet gas reservoir, condensate gas-rich reservoir, condensate gas-poor reservoir and dry gas reservoir. The causes for the diversities in oil and gas phases include diversities of the sources of parent material, maturity of natural gas and the process of hydrocarbon accumulation of different hydrocarbon phases. On the whole, the Jurassic and Triassic terrestrial source rocks are the main sources for the hydrocarbon in the Kuqa Depression. The small differences in parent material may cause diversities in oil and gas amount, but the impact is small. The differences in oil and gas phase are mainly affected by maturity and the accumulation process, which closely relates with each other. Oil and gas at different thermal evolution stage can be captured in different accumulation process.     

利用中国静止气象卫星资料估算黄河源区蒸散发量

以黄河源区为研究区域,选取2009年9月该区域的中国静止气象卫星(FY-2D)观测资料,结合地面气象观测资料,基于能量平衡原理,估算了研究区域的逐时陆面蒸散发量。结果表明:在晴天条件下,利用陆表能量平衡系统模型求出蒸散发量的大小;在阴天条件下,利用FY-2D云顶反照率资料,根据太阳辐射在大气中的衰减过程,得出地表太阳辐射收支,进而求出蒸散发量的大小。卫星遥感估算的逐时蒸散发量与地面观测值相比,平均相对误差15.2%,估算误差在可接受的合理范围内,为实现陆面蒸散发量的业务化奠定了一定的基础。     

竖向荷载下GRF承载机制数值模拟研究

岩土加固基础（geo-reinforcement foundation,简称GRF）是一种新型岩土增强型桩基础,其承载机制目前尚未明确。通过建立GRF的三维非线性模型,并考虑地基中的桩-土接触、锚杆-土接触效应,利用岩土专业计算软件FLAC3D,分析研究了GRF桩土变形以及土体屈服特性、桩身轴力变化规律、侧阻力和端阻力的变化规律。数值计算结果表明：GRF更能调动桩周土体来承载,其侧阻力、端阻力、极限承载力均大于等直径桩;由于锚杆作用,GRF的桩身轴力在锚杆附近出现“台阶式”突降;锚杆作用的发挥与桩顶位移密切相关,只有在桩顶产生一定位移条件下,锚杆才能发挥其承载作用,且土体在锚杆上部形成松弛区,在锚杆下部形成压密区;锚杆随桩体向下移动,与桩体相互作用,锚杆下部及锚杆附近桩体内会产生拉应力。研究结果为GRF在工程中推广应用奠定了一定的理论基础,对设计GRF有一定的参考价值。     

Basic Types and Structural Characteristics of Uplifts: An Overview of Sedimentary Basins in China

The uplift is a positive structural unit of the crust. It is an important window for continental dynamics owing to its abundant structural phenomena, such as fault, fold, unconformity and denudation of strata. Meanwhile, it is the very place to store important minerals like oil, natural gas, coal and uranium. Giant and large-scale oil and gas fields in China, such as the Daqing Oilfield, Lunnan-Tahe Oilfield, Penglai 19-3 Oilfield, Puguang Gas Field and Jingbian Gas Field, are developed mainly on uplifts. Therefore, it is the main target both for oil and gas exploration and for geological study. The uplift can be either a basement uplift, or one developed only in the sedimentary cover. Extension, compression and wrench or their combined forces may give rise to uplifts. The development process of uplifting, such as formation, development, dwindling and destruction, can be taken as the uplifting cycle. The uplifts on the giant Precambrian cratons are large in scale with less extensive structural deformation. The uplifts on the medium- and small-sized cratons or neo-cratons are formed in various shapes with strong structural deformation and complicated geological structure. Owing to changes in the geodynamic environment, uplift experiences a multi-stage or multi-cycle development process. Its geological structure is characterized in superposition of multi-structural layers. Based on the basement properties, mechanical stratigraphy and development sequence, uplifts can be divided into three basic types ? the succession, superposition and destruction ones. The succession type is subdivided into the maintaining type and the lasting type. The superposition type can be subdivided into the composite anticlinal type, the buried-hill draped type, the faulted uplift type and the migration type according to the different scales and superimposed styles of uplifts in different cycles. The destruction type is subdivided into the tilting type and the negative inverted type. The development history of uplifts and their controlling effects on sedimentation and fluids are quite different from one another, although the uplifts with different structural types store important minerals. Uplifts and their slopes are the main areas for oil and gas accumulation. They usually become the composite oil and gas accumulation zones (belts) with multiple productive formations and various types of oil and gas reservoirs.