甘肃天水夏家坪金矿地质特征

夏家坪金矿位于西秦岭反＂S＂弧形构造东段Au-Ag-Cu-Fe-Pb-Zn成矿带中,矿体产出受下古生界李子园群沉积-火山岩系控制。矿体多呈带状、透镜状产出,具收缩膨大、尖灭再现及分支复合特征。容矿岩石主要为变砂（泥）岩、破碎石英脉、硅化角砾岩等。矿石类型以构造蚀变岩型为主,局部为石英脉型。围岩蚀变具分带性,矿化可分为早期的金和晚期的银铅锌两个主要成矿阶段。     

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

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。     

土石坝边坡稳定性分析的温控参数折减有限元法

将土石坝渗流的有限元计算和坝坡稳定分析的强度折减有限元法相结合,对土石坝坝坡的稳定性进行分析。考虑渗流作用时,首先采用有限元法计算坝体渗流场,通过迭代计算出稳定渗流的逸出点和浸润线位置,并根据水力梯度计算坝体所受的渗透力;然后将渗流分析所确定的渗流力与土体自重、浮力、地震力等荷载共同施加在坝体上,采用温控参数折减有限元法计算土石坝坝坡的临界失稳状态及其所对应的安全系数。分析结果表明,采用此方法进行土石坝坝坡稳定分析是合理的,且大大提高了计算效率     

有关蛇绿岩研究的一些新进展

本文扼要介绍有关蛇绿岩的形成环境、成因类型划分及有关上地幔岩变形特征方面的新成果。     

库车坳陷地质结构及油气带预测

利用油气地震勘探成果和露头的岩性资料 ,对库车坳陷地震层序进行划分 ,初步认为第三系膏盐层和三叠 -侏罗系煤层及泥岩是分布比较稳定的区域性软弱层 ,构成了区域内的主要滑脱面。将库车坳陷划分 6个构造带 ,对库车坳陷的构造样式进行归纳总结 ,并结合典型实例 ,采用平衡地质剖面技术对重要剖面进行地质平衡解译 ,使库车坳陷地质结构更加清晰。结合该区油气成藏的地质条件 ,划分出若干油气聚集带 ,对各油气聚集带进行分别评价     

高放废物处置库预选场地地学信息库的建立

本文以高放废物处置库预选场地甘肃北山玉门镇地学信息库的建立为例,详细阐述了地理信息系统在高放废物地质处置中的应用,并在此基础上分析了其应用前景,为不同层次的管理、科研人员提供了全新思路;介绍了将地理信息系统技术引入图件和资料管理的优点。     

先锋盆地小龙潭组巨厚煤层煤相特征

通过２９个煤样的显微组分观察和定量分析,结合氯仿沥青“Ａ”族组分分析和饱和烃气相色谱分析,对先锋盆地上第三系中新统小龙潭组（Ｎ１ｘ）巨厚煤层的煤相特征进行了研究。结果表明该厚煤层形成期间泥炭沼泽经历了一次大的由浅变深、又由深变浅的水深变化,总体上属于低位沼泽。该厚煤层具有以陆生高等植物为主、以水生高等植物为辅的混合生源,山间盆地优越的气候水文条件、良好的聚集场所和充足的成煤原始物质最终在中新世早期稳定下沉的泥炭沼泽环境中形成了巨厚煤层     

关于中国煤层瓦斯区域分布的几点认识

据１９９４￣１９９６年连续３年的统计,全国煤矿瓦斯灾害伤亡人数占煤矿伤亡总人数的４０％以上,瓦斯涌出规律、瓦斯涌出量预测、瓦斯突出预测仍是煤矿安全技术的难题,在加强对瓦斯灾害综合治理的同时,把瓦斯作为煤层气资源积极进行开发利用,是当前的研究方向,瓦斯区域分布规律研究可以概括为建立在煤层瓦斯生成条件、保存条件基础上的高斯赋存量,高瓦斯涌出量,低瓦斯赋存量,低瓦斯涌出量区域分布规律研究;建立在高瓦斯赋     

夹皮沟金矿深部成矿预测研究

系统研究了夹皮沟地区二道沟、庙岭、大猪圈、下戏台和东坨腰子等矿床矿体和近矿围岩微量元素、矿石矿物组合和黄铁矿热电系数等的垂直变化特征,认为三者具有相互一致的变化规律,即：与热液金矿床通常的分带性相比,具有逆向分带的现象,这种特征被认为是多层次正常分带上下叠加的产物,反映夹皮沟地区金矿床在垂向上普遍存在着多个富集地段.据此预测二道沟、庙岭、大猪圈、下戏台和东坨腰子等矿床在目前的开采深度下部仍有发现深部矿体的可能.     

Geological, geochemical characteristics and isotope systematics of the Longqiao iron deposit in the Lu-Zong volcano-sedimentary basin, Middle-Lower Yangtze (Changjiang) River Valley, Eastern China

The Middle-Lower Yangtze (Changjiang) River Valley metallogenic belt is located on the northern margin of the Yangtze Craton of eastern China. Most polymetallic deposits in the Changjiang metallogenic belt are clustered in seven districts where magmatism of Mesozoic age (Yanshanian tectono-thermal event) is particularly extensive. From west to east these districts are: E-dong, Jiu-Rui, Anqing-Guichi, Lu-Zong, Tong-Ling, Ning-Wu and Ning-Zhen. World-class iron ore deposits occur in the Lu-Zong and Ning-Wu ore clusters, which are mainly located in continental fault-bound volcanic-sedimentary basins. One of these deposits is the Longqiao iron deposit, discovered in the northern part of the Lu-Zong Basin in 1985. This deposit consists of a single stratabound and stratiform orebody, hosted in sedimentary carbonate rocks of the Triassic Dongma'anshan Formation. A syenite pluton (Longqiao intrusion) is situated below the deposit. The iron ore is massive and disseminated and the ore minerals are mainly magnetite and minor pyrite. Wall rock alteration mostly consists of skarn minerals, such as diopside, garnet, potassic feldspar, quartz, chlorite, phlogopite and anhydrite. Thin sedimentary siderite beds of Triassic age occur as relict laminated ore at the top and the margin of the magnetite orebody. These sideritic laminae are part of Triassic evaporite-bearing carbonate deposits (Dongma'anshan Formation).Sulfur isotopic compositions show that the sulfur in the deposit was derived from a mixture of magmatic hydrothermal fluids and carbonate–evaporite host rocks. Similarly, the C and O isotopic compositions of limestones from the Dongma'anshan Formation indicate that these rocks interacted with magmatic hydrothermal fluids. The O isotopic compositions of the syenitic rocks and minerals from the deposit show that the hydrothermal magnetite and skarn minerals were formed from magmatic fluids. The Pb isotopic compositions of sulfides are similar to those of the Longqiao syenite. Phlogopite coexisting with magnetite in the magnetite ores yielded a plateau age of 130.5 ± 1.1 Ma (2σ), whereas the LA-ICP MS age of the syenite intrusion is 131.1 ± 1.5 Ma, which is slightly older than the age of phlogopite.The Longqiao syenite intrusion may have crystallized from a parental alkaline magma, generated by partial melting of lithospheric mantle, during extensional tectonics. The ore fluids were probably first derived from magma at depth, later emplaced in the sedimentary rocks of the Dongma'anshan Formation, where it interacted with siderite and evaporite-bearing carbonate strata, resulting in the formation of magnetite and skarn minerals. The Longqiao iron deposit is a skarn-type stratabound and stratiform mineral system, genetically and temporally related to the Longqiao syenite intrusion. The Longqiao syenite is part of the widespread Mesozoic intracontinental magmatism (Yanshanian event) in eastern China, which has been linked to lithospheric delamination and asthenospheric upwelling.