内蒙古科右前旗保隆南沟-老敖沟银铅锌矿成矿地质特征及找矿前景

通过对内蒙古保龙南沟-老敖沟银铅锌矿成矿地质特征的分析研究,认为该区矿体严格受构造蚀变带控制,属于典型的热液型银铅锌矿床,且矿区深部及周边地区尚有较大的找矿远景。     

锡在高温气相里的迁移实验与南岭大厂 矿区100号矿体形成机制

我国著名大型锡矿大厂矿区的100号矿体是一个不规则的大脉状矿体,由质密锡铅锌矿石组成。该大脉矿体长度约1200多米。大厂矿区矿床形成过程有两个主要矿化阶段:早期锡石硫化物阶段和晚期的硫盐锡石多金属矿化阶段。矿物流体包体数据表明:早期形成于300~400℃(450℃)条件下,有高盐度流体包体与低盐度流体包体共存,流体处于从超临界流体进入近临界的气液两相不混溶区过渡阶段,有流体沸腾现象;晚期流体盐度变化小处于降温过程。而100号矿体形成于300~360℃,压力较低,仅为8.24MPa。本次研究设计一含锡溶液从超临界态进入亚临界态的气液不混溶区的实验,研究金属在气-液间再分配过程。实验模拟一个非平衡的气液分离反应动力学过程。重点研究含Sn-NaHCO3-HCl-H2O在近临界压(25~22MPa)和8~14MPa、380~300℃条件下,在亚临界态气-液两相不混溶区时相分离过程。气液分离实验是恒压降温过程。结果表明:近临界区NaHCO3-HCl-H2O的NaCl-H2O体系出现气-液(L-V)分离现象。降温远离临界点时,在V与L相里的Na、Cl浓度比:Na(V/L)、Cl(V/L)比值多数远小于1,Na、Cl主要分布在液相里。实验表明出现含Sn溶液的V-L两相分离过程,并且,Sn已在L-V间再分配,Sn(V/L)多数大于1。说明Sn多数情况下分布于气相里(贫NaCl富H2OCO2)。在380~250℃范围内NaCl-H2O-CO2体系包含的H2O-CO2体系也出现V-L两相不混溶区。实验发现H2O-CO2的L-V分离过程中,气相里HCO-3和CO2-3分布很少,CO2多。同时,锡在H2O-CO2的L-V间也存在再分配,锡分布在富CO2气体里。实验说明富CO2气体迁移锡。实验为地质解释提供依据,说明100号矿体形成于快速减压的大型裂隙条件下。在300~360℃下压力减低,使含金属流体迅速进入L-V两相不混溶区,气体快速迁移金属,快速沉积金属矿石。     

青藏高原羌塘盆地早侏罗世晚期海螂蛤页岩及其年代地层学意义

发现于德国南部的早侏罗世土亚辛期的海螂蛤页岩相沉积是中生代最早一次,也是唯一保存在大陆地层中的全球性大洋缺氧事件的典型代表。近年中国羌塘盆地已相继发现4处海螂蛤页岩相地层。北羌塘天然气水合物钻探试验井QK-5井钻遇含海螂蛤页岩相特有化石组合的地层,厚度逾150m,是迄今所知羌塘盆地纬度最高的海螂蛤页岩相产地,其他3处分布在羌塘盆地中间隆起带以南的双湖和色哇等地。海螂蛤页岩相的分布纵贯南、北羌塘,意味着羌塘盆地在早侏罗世并没有受到中间隆起带的制约而分成南、北2个独立的沉积凹陷。北羌塘西部白龙冰河、半岛湖一带与东部雀莫措、雁石坪一带的早侏罗世沉积相截然不同,形成早侏罗世西海东陆的沉积格局。海螂蛤页岩相在羌塘盆地的发现,有助于进一步认识中生代羌塘盆地沉积和古海洋演化历史。该区以海螂蛤黑色页岩为代表的富碳沉积无论是分布面积还是沉积厚度都十分可观,对盆地的天然气水合物、页岩气及常规油气勘探具有重要的意义。     

安徽省庐枞盆地高岭土矿的成矿规律、找矿方向及开发应用问题探讨

庐枞盆地是以中、下侏罗统陆相碎屑岩建造为基底,经燕山运动而发育起来的陆相继承性火山岩盆地,是长江中下游地区重要的矿产地之一。盆地北部高岭土矿化普遍且强烈,具有很好的找矿远景。本文初步探讨了庐枞盆地高岭土成矿规律、矿床成因及找矿方向,提出了下一步开发利用的建议。     

辽宁岫岩地区岫玉成矿规律探讨

岫岩是我国主要蛇纹石玉产地,辽河群大石桥组大理岩层是岫岩玉石矿最重要的蕴矿层位,矿体严格受地层中韧性变形变质构造带和元古宙花岗岩的控制。在岫岩不仅产有蛇纹石岫玉,还产出透闪石岫玉。矿体形态呈不规则脉状及透镜状产出。岫岩地区的岫玉矿床成因应属于热液交代蚀变矿床类型。     

地震微裂群区与岩浆热液成矿

岩浆热液矿床是在地壳浅部形成的,恰好位于浅源地震的震源深度范围.文章将地震机制中的微裂隙群区理论引入到岩浆热液矿床成矿过程中,地震组合模式中闭锁带必须在下一次断裂滑动之前破坏,所以这个带为微裂群区和它相关的震源区的核心.文章认为微裂群区理论不但揭示了孕震机制,同时也揭示了岩浆热液矿床形成过程,岩浆热液侵位与断裂形成过程中微裂群区的形成发展密切相关,成矿期矿体范围内应力场与区域应力场呈共轭关系.微裂群区即为岩浆热液矿床的矿化富集场,控矿的隐爆角砾岩带也与微裂群区密切相关.     

硬岩型铀矿化(点、带)地球物理特征

为了深入研究硬岩型铀矿化(点、带)的地球物理特征,在桃山、红山子地区开展了综合物探测量.结果表明,在△T磁异常平面等值线图中,铀矿床(点、带)一般位于强弱磁异常过渡地带偏弱磁异常一侧,电阻率断面图中多位于高低阻梯度变化带或中低阻区,电阻率平面图中多位于中低阻过渡带偏低阻一侧.该硬岩型铀矿化地球物理特征为寻找该类铀矿有利地段提供了重要信息.     

“白烟型”热液喷流岩研究进展

现代和地质历史中的海底、湖底的“黑烟囱型”热液活动及相关成岩、成矿和古生物活动已成为当今多学科的研究热点,而与“白烟型”热液喷流岩相关的研究相对薄弱.在阅读大量国内外文献基础上,结合实际的研究工作,回顾了热液喷流岩的研究历史及现状,重点介绍了作为标志性低温型热液矿物白云岩成因方面的进展,认为新疆三塘湖地区的二叠系芦草沟组“白烟型”热液喷流沉积的白云岩是“原生白云岩”的典型样本.现有资料表明已经报道的“白烟型”热液喷流岩发育层位(酒西盆地下沟组与三塘湖盆地芦草沟组)是所在地区的重要生烃层系,据此讨论了如下值得关注的问题:①热液活动及其伴生的嗜热细菌生物及食物链的特殊环境,使有机质得以富集,为油气生成提供了物质基础;②幔源物质的加入很可能带来了幔源烃类;③热液活动可使沉积盆地地温总体升高,加速烃源岩的快速成熟.最后对该领域的研究提出了问题和建议.     

Response and recovery of the Eel River, California, and its tributaries to floods in 1955, 1964, and 1997

Northwestern California is prone to regional, high magnitude winter rainstorms, which repeatedly produce catastrophic floods in the basins of the northern Coast Ranges. Major floods on the Eel River in 1955 and 1964 resulted in substantial geomorphic changes to the channel, adjacent terraces, and tributaries. This study evaluated the changes and the effects of a moderate flood in 1997 through field observations and examination of aerial photographs that spanned from 1954 to 1996. The purpose was to document the nature and magnitude of geomorphic responses to these three floods and assess the rates and controls on the recovery of the Eel River and its tributaries. Channel widening from extensive bank erosion was the dominant geomorphic change along the lower Eel River during major floods. As a result of the 1964 flood, the largest amount of widening was 195 m and represented an 80% change in channel width. Channel narrowing characterized the periods after the 1955 and 1964 floods. More than 30 years after the 1964 flood, however, the river had not returned to pre-flood width, which suggests that channel recovery required decades to complete. A long recovery time is unusual given that the Eel River is located in an area with a “superhumid” climate and has an exceptionally high sediment yield. This long recovery time may reflect highly seasonal precipitation and runoff, which are concentrated in 3–5 months each winter. In contrast to the main stem of the Eel River, the dominant effects of floods on the tributaries of the Eel River were rapid aggradation of channel bed and valley floor followed by immediate downcutting. Dendrogeomorphic data, aerial photographs, and field observations indicate that thick wedges of gravel, derived largely from hillslope failures in upper reaches of the tributaries, are deposited at and immediately upstream of the mouths of tributaries as the stage of the Eel River exceeded that of the tributaries during major floods. In the waning stages of the flood, the tributaries cut through the gravel at a rate equal to the lowering of the Eel and generated unpaired terraces and nickpoints. The complete process of deposition and incision can occur within a few days of peak discharge. Although reworking of some sediment on the valley floor may continue for years after large floods, channel morphology in the tributaries appears to be a product of infrequent, high magnitude events. The morphology of the tributary channel also appears to be greatly influenced by the frequency and magnitude of mass wasting in headwater areas of small basins.