铁岭凡河地区元古宙地层格架建立初探

铁岭凡河地区元古宙地层始于凡河元古宙坳拉谷沉积，根据岩石地层学、生物地层学、年代地层学等研究成果，结合现代层序地层学理论，自下而上划分六个层序，即关门山层序，虎头岭层序、二道沟层序、石门层序、杨士屯层序、于北沟层序。每个层序仅由海侵体系域和高水位体系域组成，分别代表海侵退积地层结构和海退进积地层结构，而中间饥饿段则以加积为主。各层序间均为不整合，其类型包括海岸暴露带和海侵面。在此基础上，建立了区域地层格架。     

Mineralization of the Liwu large-scale stratiform copper deposits in Sichuan Province,China: Constraints from fluid inclusions

The Liwu stratiform copper deposit is located in the northwestern Jianglang dome, western China. Current studies mainly focus on the genetic type and mineralization of this deposit. Detailed fluid inclusion characteristics of metallogenic period quartz veins were studied to reveal the ore-forming fluid features. Laser Raman analysis indicates that the ore-forming fluids is a H₂O-NaCl-CH₄ (-CO₂) system. Fluid inclusions microthermometry shows a homogenization temperature of 181–375°C and a salinity of 5.26%–16.99% for the disseminated-banded Cu-Zn mineralization; but a homogenization temperature of 142–343°C and a salinity of 5.41%–21.19% for the massive-veined Cu-Zn mineralization. These features suggest a medium-high temperature and a medium salinity for the ore-forming fluids. H-O isotopic data indicates that the ore-forming fluids were mainly from the metamorphic and magmatic water, plus minor formation water. And sulfur isotopic data indicates that sulfur was mainly derived from the formation and magmatic rocks. Metallogenesis of the disseminated-banded mineralization was mainly correlated with fluid mixing and water-rock reaction; whereas that of the massive-veined mineralization was mainly correlated with fluid boiling. The genetic type of the deposit is a medium-high temperature hydrothermal deposit related to magmatism and controlled by shear zones. This study is beneficial to understand the stratiform copper deposit.©2023 China Geology Editorial Office.     

新疆阔尔真阔腊金矿床成矿流体包裹体研究

新疆西北部阔尔真阔腊金矿床是产于海西期岛弧型钙碱性火山岩中的火山晚期热液型金矿床。流体包裹体研究表明,成矿阶段(Ⅰ)包裹体为气相包裹体,均一温度为308～396℃,盐度为5．86～8．41wt％NaCl;主成矿阶段(Ⅱ、Ⅲ)为气液包裹体,均一温度分别为209～276℃(Ⅱ)、119～198℃(Ⅲ),盐度分别为5．11～7．86wt％NaCl(Ⅱ)、2．74～6．17wt％NaCl(Ⅲ)。石英流体包裹体成分测定采用分阶段法,有效地排除了不同成矿阶段包裹体成分的影响,准确地测出了成矿阶段(Ⅰ)和主成矿阶段(Ⅱ、Ⅲ)包裹体的成分,结果表明成矿流体具Na^ -H^--Cl^--H2O型中低温、低盐特征,金主要以金硫络合物的形式迁移,金矿化是在还原条件下进行。主成矿阶段包裹体中水的氢同位素组成为-83．97～-89．07‰,氧同位素组成为1．8～3．2‰,成矿流体是岩浆热液与古大气降水混合而成。流体混合及水-岩反应是造成本区金沉淀成矿的主要因素。     

胶东金矿区夏甸金矿床矿化分布规律及构造控矿分析

夏甸金矿床是胶西北地区典型的蚀变岩型金矿床,金矿化主要受招平断裂带控制。本文对夏甸金矿床进行了野外地质调查,三维地质建模和构造空间分析,以期从三维空间和勘查数据中厘清矿化分布规律、探明构造控矿作用。研究结果显示,夏甸金矿床矿化主要为蚀变岩型和硫化物脉型,主要受招平断裂带及其次级构造控制,在空间中呈现出不均一分布的特征。夏甸金矿床的矿化侧伏规律,在空间中存在差异性,其中南部为NE侧伏,中段侧伏规律不明显但分支复合特征明显,而北段呈SE侧伏。这种侧伏规律与招平断裂带主裂面在走向方向的转折密切相关。进一步的空间分析显示,夏甸金矿床不同类型的矿体是不同空间范围内构造变形差异的结果。     

塔克拉玛干沙漠地下水矿化度与电导率关系的研究

用数理统计的方法推导水质矿化度与电导率的回归方程, 并绘制其关系曲线。经测定, 新疆塔克拉玛干沙漠84°E沿线水化学类型主要为Cl^-·SO₄^2--Na⁺, 通过推导得出, 25℃情况下, 当电导率为4.5~12ms/cm, 矿化度依电导率的回归方程为: y=-0.3016+0.6936x; 当电导率<5.4ms/cm, y=-0.171+0.6833x, 建立矿化度与电导率的关系后, 测定地下水的电导率, 即可获得待测样的矿化度, 为野外考察或定点观测提供获得地下水矿化度的简便、快速而准确的方法。     

东太平洋铁锰结核区微生物的丰度及其成矿作用研究

于１９９４年４－１１月东太平洋铁锰结核期探区,随向阳红０９号船,采集了３９个表层沉积物,１２个上覆水和７个结核样,在现场用平板法测定了异养细菌和铁,锰细菌丰度,用稀释法（ＭＰＮ法）测定硫酸盐还原菌丰度,在实验室对船上带回的异养细菌和锰细菌进一步纯分分离,进行了１２项生化试验,对照伯杰氏手册第八版鉴定至属。为了探讨微生物在大洋成矿过程的作用,使用分光光度法,测定锰细菌对锰,铁离子的转化作用和不同培养     

西天山石炭纪火山-沉积盆地铁锰矿成矿规律浅析

西天山石炭纪火山-沉积盆地是在穆云库姆-克齐尔库姆-伊犁微板块上形成的陆缘盆地,在伊犁石炭—二叠纪裂谷带发展过程中,经历了拉张至稳定再拉张、火山活动剧烈→平静→强烈的地质构造及火山活动发展过程,控制了盆地内以铁为主的火山成矿作用、火山-沉积成矿作用及化学沉积成矿作用,形成了西天山海相火山-沉积型铁(锰)矿床,具有距火山活动中心由近到远,成矿类型由火山喷溢堆积型至火山沉积型再到化学沉积型的变化规律.     

吉林省夹皮沟金矿带几个重要地质问题的讨论

夹皮沟金矿带位于吉林省东南部桦甸地区。自1820 年发现以来,已累计探明黄金地质储量150 吨左右。该金矿带位于中朝古板块北缘东段与布列亚-佳木斯地块南缘的碰撞对接部位附近。区内发育5 条平行的NW 向含矿构造带,其北端均以锐角交汇于挥发河断裂。有别于前人的研究成果,本文提出夹皮沟金矿带恰好位于高级区与夹皮沟花岗-绿岩带的接触部位,形成以夹皮沟金矿化带为中心的矿化分带。夹皮沟金矿带为中生代成矿,夹皮沟NW 向弧形构造片理化带及其上盘扇状断裂系控制着金矿床的分布。在主要NW 构造带之间,还存在一系列与之平行的次级构造,它们与扇状断裂的交汇点及扇状构造系中的横向应力集中带是金矿化定位的有利部位。     

Spatial–temporal variability in water quality and macro-invertebrate assemblages in the Upper Mara River basin,Kenya

Tropical rivers display profound temporal and spatial heterogeneity in terms of environmental conditions. This aspect needs to be considered when designing a monitoring program for water quality in rivers. Therefore, the physico-chemical composition and the nutrient loading of the Upper Mara River and its two main tributaries, the Amala and Nyangores were monitored. Initial daily, and later a weekly monitoring schedule for 4 months spanning through the wet and dry seasons was adopted. Benthic macro-invertebrates were also collected during the initial sampling to be used as indicators of water quality. The aim of the current study was to investigate the physico-chemical status and biological integrity of the Upper Mara River basin. This was achieved by examining trends in nutrient concentrations and analyzing the structure, diversity and abundance of benthic macro-invertebrates in relation to varying land use patterns. Sampling sites were selected based on catchment land use and the level of human disturbance, and using historical records of previous water quality studies. River water pH, dissolved oxygen, electrical conductivity (EC), temperature, and turbidity were determined in situ. All investigated parameters except iron and manganese had concentration values within allowable limits according to Kenyan and international standards for drinking water. The Amala tributary is more mineralized and also shows higher levels of pH and EC than water from the Nyangores tributary. The latter, however, has a higher variability in both the total phosphorus (TP) and total nitrogen (TN) concentrations. The variability in TP and TN concentrations increases downstream for both tributaries and is more pronounced for TN than for TP. Macro-invertebrate assemblages responded to the changes in land use and water quality in terms of community composition and diversity. The study recommends detailed continuous monitoring of the water quality at shorter time intervals and to identify key macro-invertebrate taxa that can be used to monitor changes of the water quality in rivers of the Mara basin as a result of anthropogenic changes.