青海省天峻县木里煤田煤层气有利区块的 多层次模糊数学评判     

邵龙义  文怀军  李永红  周俊  蔡玉良  贾志燿  鲁静 《地质通报》2011,30(12):1896-1903

对影响煤层气勘探开发潜力的各种因素进行了综合研究,确定了煤层气勘探开发潜力评价的3个二级指标(生气潜力、储层物性和封盖性能)及对应的三级指标。采用模糊数学方法对各级因素指标赋予权重,建立了用于煤层气勘探开发潜力评价的多层次模糊数学评判模型。利用该模型,对青海木里煤田中低煤阶煤层气资源勘探开发潜力进行了评价,认为江仓矿区是木里煤层气勘探开发的最佳试验区。所建立的评价体系可以作为中低煤阶煤层气资源开发潜力评价的参考体系。  相似文献   

Heat flow pattern, base of methane hydrates stability zones and BSRs in Shenhu Area, northern South China Sea   总被引：2，自引：2，他引：0  

ZHANG Yi  HE Lijuan  WANG Jiyang  XU Xing  SHA Zhibing  GONG Yuehu  WANG Hongbing  LIANG Jinqiang 《海洋学报(英文版)》2011,30(1):59-67

Using the collected 433 heat flow values, we estimated the bases of methane hydrate stability zone (BHSZ), in northern South China Sea (NSCS). Through comparing BHSZs with the depths of bottom simulating reflectors (BSRs), in Shenhu Area (SA), we found that there are big differences between them. In the north of SA, where the water depth is shallow, many slumps developed and the sedimentation rate is high, it appears great negative difference (as large as -192%). However, to the southeast of SA, where the water depth is deeper, sedimentation rate is relatively low and uplift basement topography exists, it changes to positive difference (as large as +45%). The differences change so great, which haven’t been observed in other places of the world. After considering the errors from the process of heat flow measurement, the BSR depth, the relationship of thermal conductivity with the sediments depth, and the fluid flow activities, we conclude that the difference should be not caused by these errors. Such big disagreement may be due to the misunderstanding of BSR. The deviant “BSRs” could represent the paleo-BSRs or just gas-bearing sediment layers, such as unconformities or the specific strata where have different permeability, which are not hydraterelated BSRs.  相似文献   

九龙江河口沉积物中硫酸盐还原与甲烷厌氧氧化:同位素地球化学证据   总被引：5，自引：1，他引：4  

尹希杰  陈坚  郭莹莹  孙治雷  邵长伟 《海洋学报》2011,33(4):121-128

通过沉积物柱孔隙水中甲烷,SO2-4,Cl-,δc(34S-SO2-4)、δc(13 C-CH4)的垂直分布特征,研究了硫酸盐还原和甲烷厌氧氧化(anaerobic oxidation of methane,简称AOM)过程在九龙江河口沉积物中的分布规律.测定结果显示两个站位(J-A和J-E)间隙水中SO2-4浓度随深...  相似文献   

Characterisation and preliminary quantification of the methane reservoir in a coastal sedimentary source: San Simón Bay,Ría de Vigo,NW Spain     

S. García-Gil  E. de Blas  N. Martínez-Carreño  J. Iglesias  R. Rial-Otero  J. Simal-Gándara  A.G. Judd 《Estuarine, Coastal and Shelf Science》2011

Ría de Vigo is a river valley flooded by the sea, with a bay (San Simón Bay) at its innermost part. The accumulation of Holocene sediment in San Simón Bay has been studied by the integration of 1) large scale high resolution seismic data, and 2) detailed geochemical analysis of a gravity core. In San Simón Bay the majority of the seismic records are obscured by acoustic turbidity which represents gassy sediments, but on records from Rande Strait it is possible to distinguish two Quaternary seismic sequences; an Upper Pleistocene sequence (SQ1) and a Holocene sequence (SQ2). Only SQ2 is recognized in San Simón Bay where it is comprised of two seismic units; the upper unit represents the HST sediment, i.e. the period of highest sea level. A gravity core taken within the gassy zone at 10 m water depth provided 3.55 m of fine-grained sediments (muds) from the youngest seismic unit (4 m thick). Geochemical analysis show high values (4 to 10%) of TOC. Sediment and porewater analyses indicate a distinct sulphate–methane transition zone (SMTZ) between 60 and 80 cm where sulphate is depleted (to <1.7 mM) and methane increases (to >0.4 mM). The top of the acoustic turbidity (the gas front) at 80 cm corresponds to the lower limit of the SMTZ. The methane cannot have been derived from the underlying metamorphic and granitic rocks, but was probably derived by microbial degradation of the organic matter in the Holocene sediments. We estimate that the sediments of the Bay contain approximately 1.8 × 10⁶ m³ of organic carbon and 275 ton of methane.  相似文献   

Chemosynthetic trophic support for the benthic community at an intertidal cold seep site at Mocha Island off central Chile     

Javier Sellanes  Germán Zapata-Hernández  Silvio Pantoja  Gerdhard L. Jessen 《Estuarine, Coastal and Shelf Science》2011

We analyzed C and N stable isotope ratios of benthic fauna and their potential food sources at an intertidal methane seep site and a control site without emanation at Mocha Island (central Chile). The objective was to trace the origin of the main food sources used by the local heterotrophic fauna, based on the hypothesis that chemosynthetic production could be partially fueling the local food web at the seep site. Food sources sampled at both sites included macroalgae, particulate organic matter and bacteria-like filaments found growing over the red algae Gelidium lingulatum within the areas of active methane release.  相似文献   

激光拉曼光谱法在单个流体包裹体研究中的应用进展   总被引：2，自引：2，他引：0  

何佳乐  潘忠习  冉敬 《岩矿测试》2015,34(4):383-391

激光拉曼光谱法以其非破坏性、高灵敏度和高分辨率等特性,一直以来都是研究流体包裹体的重要方法之一。近年来,围绕激光拉曼光谱在流体包裹体中的应用而展开的研究主要集中在半定量-定量测试方面,即在准确定性的基础上,采用高斯-洛仑兹去卷积分峰、低温原位等定量方法获取流体包裹体的成分和含量,从而克服了激光拉曼光谱法应用于溶液中阳离子的定量分析的灵敏度、准确度较低的问题,不仅能获得流体包裹体中一些常温下不具拉曼活性的盐类物质拉曼特征峰信息,还能根据特征峰与浓度、内压之间的线性关系,进一步对盐度和压力等性质进行测定,从而拓展了激光拉曼光谱法在流体包裹体中的应用范围。本文对激光拉曼光谱法应用于分析流体包裹体成分、盐度、同位素和压力所取得的最新进展进行了评述,并认为随着分析测试技术的不断进步,激光拉曼光谱法未来的分析方向也将继续围绕多元复杂体系及其定量方面的研究展开。  相似文献   

安徽铜陵胡村南铜钼矿床流体成矿过程   总被引：1，自引：0，他引：1  

郑泽军  杜杨松  鲁颖淮  陈林杰  杨赫鸣  张芸  任春雷  江勇卫 《矿床地质》2015,34(4):692-710

胡村南铜钼矿床是在安徽铜陵铜(金)矿集区中发现的第一个矽卡岩-斑岩复合型铜钼矿床,在长江中下游成矿带具有特殊性和典型性。文章对该矿床进行了矿床地质和流体包裹体研究,旨在查明该矿床的流体成矿过程。胡村南铜钼矿床流体成矿过程可以划分为高温气成热液期、中高温热液期和低温热液期3个成矿期。高温气成热液期发育钾长石化和矽卡岩化,中高温热液期发育绿泥石化、绿帘石化和绢云母化,而低温热液期主要发育碳酸盐化。其中,中高温热液期为主要矿化期,形成辉钼矿和黄铜矿等多种硫化物网脉。高温气成热液期矿物中发育富液相和含子晶多相包裹体,中高温热液期矿物中也主要发育富液相包裹体和含子晶多相包裹体,但可见少量的富气相包裹体,低温热液期矿物中只发育富液相包裹体。从高温气成热液期经中高温热液期到低温热液期,成矿流体均一温度从435℃以上,经203~458℃,降低到156~276℃;盐度w(NaCleq)从14.0%~64.9%,经4.6%~47.5%,降低到1.0%~15.5%。成矿流体在其演化过程中发生过不混溶作用和沸腾作用。不混溶作用发生在气成热液期,使成矿流体中的成矿元素大量富集。沸腾作用发生在中高温热液期,导致成矿流体中的成矿元素卸载而沉淀出大量金属硫化物。  相似文献   

新疆阿尔泰巴特巴克布拉克铁矿床成矿作用研究   总被引：2，自引：0，他引：2       下载免费PDF全文

杨俊杰  柴凤梅  杨富全  张志欣 《地质科学》2015,(3):879-897

巴特巴克布拉克铁矿床赋存于上志留-下泥盆统康布铁堡组变质火山-沉积岩系中, 近矿围岩为石榴子石矽卡岩、角闪斜长变粒岩和浅粒岩。矿体总体顺层分布, 呈似层状、透镜状及不规则状, 空间上与矽卡岩密切相关。流体包裹体研究表明, 矽卡岩阶段形成的石榴子石中发育纯气体包裹体、气体包裹体、液体包裹体、含子矿物包裹体及熔融包裹体; 退化蚀变阶段发育液体包裹体和少量气体包裹体; 石英-硫化物阶段主要发育液体包裹体、含液体CO₂的三相包裹体及少量纯气体包裹体、气体包裹体和含子矿物包裹体。矽卡岩阶段均一温度变化为217 ℃~499 ℃, 在255 ℃出现峰值, 盐度(NaCl_eq)变化为8.68%~22.65%; 退化蚀变阶段均一温度变化为181 ℃~432 ℃, 在225 ℃出现峰值, 盐度变化为12.85%~22.65%; 石英-硫化物阶段均一温度变化为140 ℃~482 ℃, 在155 ℃出现峰值, 盐度变化为0.18%~42.40%。石榴子石、石英和方解石的 δ¹⁸ O_SMOW 变化为1.8‰~7.1‰, δ¹⁸Ο_Η2Ο为 -4.79‰~4.57‰, δD_SMOW 为 -128‰~-84‰, 表明矽卡岩阶段成矿流体主要为岩浆水, 混合少量大气降水; 石英-硫化物阶段大气降水所占比例明显增加。方解石δ¹³ C_V-PDB 变化为 -3.2‰~-2.0‰, 表明流体中的碳来自深部或地幔。  相似文献   

南堡凹陷下古生界流体包裹体特征及成藏期研究     

朱文慧  曲希玉  查明  邱隆伟  张红臣  唐惠 《世界地质》2015,34(1):148-156

通过流体包裹体的透射光和荧光镜下观察、包裹体均一温度测定,对南堡凹陷下古生界碳酸盐岩流体包裹体特征及油气成藏期进行了研究。结果表明:南堡凹陷下古生界碳酸盐岩储层流体包裹体较为发育,主要在碳酸盐岩脉中沿愈合裂缝呈带状分布,烃类包裹体在荧光下呈黄白色--蓝白色,说明研究区油气成熟度相对较高;由包裹体均一温度实测结果可知,该区包裹体均一温度具有明显的双峰特征,峰值分别为70℃~80℃和130℃~140℃;结合埋藏史和热演化史进行综合研究,认为研究区下古生界碳酸盐岩储层主要经历了两期油气充注,第一期为25~22 Ma(东营末期—馆陶早期),第二期为8~5 Ma(明化镇中期)。  相似文献   

Ore-forming Fluid Characteristics of the Saishitang Cu-polymetallic Deposit in Qinghai Province, China     

LAI Jianqing  JU Peijiao  MAO Yin  AN Jianghu  WANG Xiongjun 《《地质学报》英文版》2015,89(2):485-504

Saishitang Cu-polymetallic deposit is located in the southeast section of Late Paleozoic arcfold in the southeastern margin of Qaidam platform. Accoring to the geological process of the deposit,four mineralization episodes were identified: melt/fluid coexisting period(O),skarn period(A),first sulfide period(B) and second sulfide period(C),and 10 stages were finally subdivided. Three types of inclusions were classified in seven stages,namely crystal bearing inclusions(type I),aqueous inclusions(type II) and pure liquid inclusions(type III). Type I and II inclusions were observed in stage O1,having homogenization temperature from 252 to 431°C,and salinities ranging from 24.3% to 48.0%. Type I inclusion was present in stage A1,having homogenization temperature from 506 to 548°C,and salinities ranging from 39.4% to 44.6%. In stage B1,type II and III inclusions were observed,with homogenization temperature concentrating between 300–400°C,and salinities from 0.4% to 4.3%. Type II inclusions were present in stage B2,with homogenization temperature varying from 403 to 550°C. In stage C1,type I and II inclusion commonly coexisted,and constituted a boiling inclusion group,having homogenization temperatures at 187–463°C,and salinities in a range of 29.4%–46.8% and 2.2%–11.0%. Type II and III inclusions were developed in stage C2,having homogenization temperature at 124–350°C,and salinities ranging between 1.6% and 15.4%. In stage C3,type II and III inclusions were presented,with a homogenization temperature range of 164–360°C,and salinities varying from 4.0% to 11.0%. The results of micro-thermal analysis show that fluids are characterized by high temperature and high salinity in stage O1 and A1,and experienced slight decrease in temperature and dramatic decrease in salinity in stage B1 and B2. In stage C1,the salinity of fluid increased greatly and a further decrease of temperature and salinity occurred in stage C2 and C3. Fluids boiled in stage C1. With calculated pressure of 22 MPa from the trapping temperature of 284–289°C,a mineralization depth of 2.2 km was inferred. Results of Laser Raman Spectroscopy show high density of H2 O,CH4 and CO2 were found as gas composition. H-O isotope study indicates the oreforming fluids were the mixture of magmatic water and meteoric water. Physicochemical parameters of fluids show oxygen and sulfur fugacity experienced a decrease,and redox state is weakly reducing. Along with fluid evolution,oxidation has increased slightly. Comprehensive analysis shows that melt exsolution occurred during the formation of quartz diorite and that metal elements existed and migrated in the form of chlorine complex. Immiscible fluid separation and boiling widely occurred after addition of new fluids,bringing about dissociation of chlorine-complex,resulting in a great deal of copper precipitation. In conclusion,Saishitang deposit,controlled by regional tectonics,is formed by metasomatism between highly fractionated mineralization rock body and wall rock,and belongs to banded skarn Cu-polymetallic deposit.  相似文献