贵州遵义二叠纪锰矿气液喷口群的发现及地质意义

在通过对遵义市锰矿整装勘查区及周边所有探矿工程资料整理、分析研究的基础上,结合野外大比例尺专项地质填图、剖面实测和测试的成果。将贵州遵义二叠系锰矿与华南古天然气渗漏沉积型锰矿床成矿理论进行详细对比,认为遵义锰矿总体是"内生外成",成锰物质主体来自地幔,遵义锰矿属"古天然气渗漏沉积型锰矿床",借鉴古天然气渗漏沉积型锰矿床的成矿理论和研究方法,运用遵义锰矿裂陷槽盆地结构的划分、同沉积断裂的识别和中心相、过渡相和边缘相判别标志,在断陷盆地中喷溢口及附近,发现矿石及其顶底板具有古天然气渗漏沉积型锰矿床独有的结构构造、同位素、生物组合等特征。研究认为遵义成锰盆地至少存在5个气液渗漏喷溢口,分布于Ⅲ级断陷盆地内,每一个喷溢口构成一个相对独立的气液渗漏喷溢沉积成矿系统,遵义锰矿床是形成由若干个气液渗漏喷溢沉积成矿子系统构成的沉积成矿系统。贵州遵义二叠纪锰矿成矿的气液渗漏喷溢口的发现,对遵义锰矿"内生外成"成因研究提供了宏观地质证据,为建立深部锰矿找矿预测模型提供了重要依据,为研究遵义锰矿的古天然气渗漏沉积型锰矿床成矿系统具有重要意义。     

贵州遵义深溪大型锰矿床主要地质特征

贵州遵义地区是我国二叠纪锰矿的重要分布区之一,深溪锰矿是遵义地区继铜锣井锰矿发现的第二个大型隐伏锰矿床。本文结合深溪锰矿找矿实践,详细总结了深溪锰矿床地层、构造、矿石等特征,并对锰矿的矿床成因进行了探讨。研究表明,深溪锰矿严格受地层层位控制,呈层状、似层状产于二叠纪茅口组第三段浅灰至灰黑色含锰岩系中,矿石矿物主要为菱锰矿,含少量黄铜矿、重晶石、毒砂等矿物,矿石为块状、斑杂状、角砾状构造,自然类型为碳酸锰矿石,工业类型为贫锰矿、富锰矿。分析认为深溪锰矿为深部的气液成矿物质喷溢至地堑盆地中沉积成矿,为"内生外成"的"古天然气渗漏沉积型锰矿床"。     

大兴安岭北段扎兰屯地区晚古生代早期花岗质岩浆作用——对额尔古纳 兴安地块和松嫩地块拼合时限的制约

扎兰屯地区位于二连 贺根山 黑河构造带中段,区内发育韧性变形叠加的晚古生代早期花岗岩类。本文在详尽的野外地质调查基础上,对该套花岗岩类的锆石U- Pb年代学和地球化学进行系统分析,研究其成岩年代序列,探讨岩石成因及构造背景,厘定韧性构造叠加的时限,进一步揭示扎兰屯地区额尔古纳 兴安地块和松嫩地块的拼合过程,为兴蒙造山带的区域构造演化研究提供新材料。大量年代学研究显示,扎兰屯地区晚古生代早期花岗质岩浆作用发生于405~325Ma之间,该作用可进一步细化为早中泥盆世(Ⅰ期、405~380Ma)、晚泥盆世—早石炭世初(Ⅱ期、365~350Ma)和早石炭世晚期(Ⅲ期335~325Ma)等3期。其中Ⅰ期和Ⅱ期花岗岩类属高钾—钾玄质钙碱性、准铝质—弱过铝质花岗岩类,可能为俯冲背景下岛弧岩浆活动形成的I型 分异I型花岗岩;Ⅲ期花岗岩类属中—高钾钙碱性、准铝质—弱过铝质花岗岩类,可能为后碰撞背景下岩浆活动形成的分异I型- A型花岗岩。该套花岗岩类普遍叠加韧性变形,可能为碰撞后侧向逃逸作用的产物,变形时限为晚石炭世末—早二叠世(308~290Ma)。大兴安岭北段晚古生代早期花岗质岩浆作用与额尔古纳 兴安地块和松嫩地块的碰撞拼合作用有关,扎兰屯地区二者的碰撞拼合时限可能为早石炭世中期。     

准噶尔盆地东北部侏罗系砂岩型铀矿成矿环境与找矿方向探讨

文章从蚀源区铀源条件、中新生代构造演化条件、侏罗系沉积建造特征及后生蚀变特征等角度分析了准噶尔盆地东北部砂岩型铀矿的区域成矿条件,认为卡拉麦里山的富铀花岗岩体为该区砂岩型铀成矿提供了丰富的铀源,中侏罗统含煤碎屑岩建造为砂岩型铀成矿提供了良好的容矿空间,侏罗纪以来多期次不整合面的发育为含铀含氧水的渗入改造提供了通道及时间,为大规模层间氧化带的发育提供了物质基础。研究结果显示,卡拉麦里山北坡为最有利的砂岩型铀矿找矿部位,其主要找矿目标层位为中侏罗统头屯河组,找矿类型为层间氧化带型。     

高效液相色谱-电感耦合等离子体质谱联用检测土壤中的无机硒形态

土壤样品中亚硒酸盐Se(Ⅳ)和硒酸盐Se(Ⅵ)的形态分析中,提取剂的选择和检测方法是技术的关键。以往的提取剂容易导致硒形态发生转变或无法同时提取Se(Ⅳ)和Se(Ⅵ),常用的氢化物发生原子荧光光谱法无法直接测定Se(Ⅵ),而是通过差减法得出Se(Ⅵ)含量。本文对比了不同提取剂的提取能力,确定使用0. 1 mol/L氢氧化钠溶液作为提取剂,在55℃超声萃取土壤样品30 min,提取液经高效液相色谱分离,电感耦合等离子体质谱检测,建立了土壤中Se(Ⅳ)和Se(Ⅵ)的形态分析方法。采用Hamilton PRP X-100色谱柱,以6 mmol/L柠檬酸为流动相,pH=5. 5,在8 min内可完全分离Se(Ⅳ)和Se(Ⅵ),两者的检出限分别为0. 15μg/L、0. 16μg/L,线性相关系数(r~2)均大于0. 999。以土壤为基体进行加标回收试验,Se(Ⅳ)和Se(Ⅵ)的回收率在84. 2%～95. 8%之间,相对标准偏差为1. 4%～5. 3%(n=6)。该方法简单快速,具有良好的精密度和准确度,适用于土壤中无机硒的形态分析。     

西藏冈底斯带昂仁县差绒—丁欧复式花岗岩的成因：锆石U-Pb年代学及地球化学制约

西藏冈底斯带昂仁县措迈乡差绒—丁欧复式花岗岩岩石类型为石英闪长岩、黑云二长花岗岩和二长花岗岩,各侵入体之间为突变接触关系,闪长岩U- Pb同位素年龄为155.4±2.7Ma;黑云二长花岗岩U- Pb同位素年龄为152.0±13Ma、153.96±0.92Ma,时代均为晚侏罗世。岩石地球化学显示三者均为高钾钙碱性系列岩石,石英闪长岩为弱铝质―准铝质;黑云二长花岗岩和二长花岗岩则为准铝质—过铝质。黑云二长花岗岩和二长花岗岩相比石英闪长岩表现为富硅、富碱、贫Ca、Ti、Mg,轻稀土元素更富集,轻稀土分馏程度更高,分异更加明显的特点,微量元素二长花岗岩Ba、Sr、P、Ti亏损最为明显,黑云二长花岗岩的Rb、Th、K富集最为明显,石英闪长岩相比黑云二长花岗岩和二长花岗岩的Rb/Sr（0.18~0.46）、Rb/Ba值（0.13~0.26）最低,指示其分异演化程度较低。差绒—丁欧花岗岩应是同时代不同期次侵入的复式岩体,早期为I型的石英闪长岩和黑云二长花岗岩,晚期为S型二长花岗岩,该复式岩体并非产出于单一的俯冲环境,二长花岗岩可能为弧陆碰撞时的产物。     

大兴安岭十八站—韩家园地区中酸性侵入岩LA-ICP-MS锆石U-Pb年龄、地球化学特征及其地质意义

大兴安岭北部塔河县十八站—呼玛县韩家园地区发育早古生代中酸性侵入岩。文章选取二长闪长岩和二长花岗岩开展岩石年代学与地球化学研究。二长闪长岩LA-ICP-MS锆石U-Pb年龄为512.4±3.5 Ma,为早—中寒武世岩浆作用的产物。岩石地球化学分析表明,中酸性侵入岩归属于准铝质—弱过铝质(A/CNK=0.77~1.04)钙碱性—高钾钙碱性系列。岩石稀土总量∑REE=69.51×10~(-6)~275.83×10~(-6),轻重稀土分异明显(La/Yb)_N=9.11~26.64。在稀土元素配分图上,显示为LREE富集、HREE相对平缓的右倾型,Eu异常不显著(δEu=0.90~1.35)。微量元素组成具明显富集大离子亲石元素Ba、Sr,显著亏损高场强元素Nb、Ta、Ti的特征。结合区域资料和本文研究,初步分析认为早古生代侵入体形成于活动大陆边缘或岛弧环境,为前古亚洲洋闭合背景下萨拉伊尔造山作用的产物。     

基于GIPL2模型的青藏高原活动层土壤热状况模拟研究

青藏高原活动层土壤热状况,对深入了解高原活动层的厚度变化特征、下垫面的热力作用以及对气候变化预测均有重要意义。利用GIPL2模型模拟青藏高原多年冻土区不同植被状况下活动层土壤热状况。模拟结果表明：模型在高寒草原（QT06）试验点模拟效果较好,高寒沼泽草甸（QT03）试验点的模拟效果较差,高寒草甸（QT01）、高寒荒漠草原（QT05）和高寒草原化草甸（QT04）试验点的模拟效果介于高寒草原试验点和高寒沼泽草甸试验点之间。QT01、QT03、QT04、QT05和QT06的土壤温度模拟值与观测值相比,均方根误差分别为0.67、1.29、0.73、0.7和0.56℃;相关系数分别为0.99、0.87、0.98、0.98和0.96;平均误差分别为0.37、0.61、0.31、0.45和0.16℃。QT06模拟结果较好,原因在于此点土壤质地变化不大,模型的分层与所取的参数更加接近此点的实际状况。QT03模拟结果较差,可能由于此地区土壤中存在砾石,在导热率参数化方案中没有考虑砾石含量,导致模拟结果偏差较大。总体而言,GIPL2模型对青藏高原活动层土壤热状况的模拟具有一定的优势,是一种模拟多年冻土区活动层土壤热状况较为理想的模型。     

Geological Controls on the CBM Productivity of No.15 Coal Seam of Carboniferous–Permian Taiyuan Formation in Southern Qinshui Basin and Prediction for CBM High-yield Potential Regions

Coalbed methane (CBM) resources in No.15 coal seam of Taiyuan Formation account for 55% of the total CBM resources in southern Qinshui Basin (SQB), and have a great production potential. This study aims at investigating the CBM production in No.15 coal seam and its influence factors. Based on a series of laboratory experiments and latest exploration and development data from local coal mines and CBM companies, the spatial characteristics of gas production of No.15 coal seam were analyzed and then the influences of seven factors on the gas productivity of this coal seam were discussed, including coal thickness, burial depth, gas content, ratio of critical desorption pressure to original coal reservoir pressure (RCPOP), porosity, permeability, and hydrogeological condition. The influences of hydrological condition on CBM production were analyzed based on the discussions of four aspects: hydrogeochemistry, roof lithology and its distribution, hydrodynamic field of groundwater, and recharge rate of groundwater. Finally, a three-level analytic hierarchy process (AHP) evaluation model was proposed for predicting the CBM potentials of the No.15 coal seam in the SQB. The best prospective target area for CBM production of the No.15 coal seam is predicted to be in the districts of Panzhuang, Chengzhuang and south of Hudi.     

Development Phases and Mechanisms of Tectonic Fractures in the Longmaxi Formation Shale of the Dingshan Area in Southeast Sichuan Basin, China

Shale gas has currently attracted much attention during oil and gas exploration and development. Fractures in shale have an important influence on the enrichment and preservation of shale gas. This work studied the developmental period and formation mechanism of tectonic fractures in the Longmaxi Formation shale in the Dingshan area of ??southeastern Sichuan Basin based on extensive observations of outcrops and cores, rock acoustic emission (Kaiser) experiments, homogenization temperature of fracture fill inclusions, apatite fission track, thermal burial history. The research shows that the fracture types of the Longmaxi Formation include tectonic fractures, diagenetic fractures and horizontal slip fractures. The main types are tectonic high-angle shear and horizontal slip fractures, with small openings, large spacing, low densities, and high degrees of filling. Six dominant directions of the fractures after correction by plane included NWW, nearly SN, NNW, NEE, nearly EW and NW. The analysis of field fracture stage and fracture system of the borehole suggests that the fractures in the Longmaxi Formation could be paired with two sets of plane X-shaped conjugate shear fractures, i.e., profile X-shaped conjugate shear fractures and extension fractures. The combination of qualitative geological analysis and quantitative experimental testing techniques indicates that the tectonic fractures in the Longmaxi Formation have undergone three periods of tectonic movement, namely mid-late Yanshanian movement (82–71.1 Ma), late Yanshanian and middle Himalaya movements (71.1–22.3 Ma), and the late Himalayan movement (22.3–0 Ma). The middle-late period of the Yanshanian movement and end of the Yanshanian movement-middle period of the Himalayan movement were the main fracture-forming periods. The fractures were mostly filled with minerals, such as calcite and siliceous. The homogenization temperature of fracture fill inclusions was high, and the paleo-stress value was large; the tectonic movement from the late to present period was mainly a slight transformation and superposition of existing fractures and tectonic systems. Based on the principle of tectonic analysis and theory of geomechanics, we clarified the mechanism of the fractures in the Longmaxi Formation, and established the genetic model of the Longmaxi Formation. The research on the qualitative and quantitative techniques of the fracture-phase study could be effectively used to analyze the causes of the marine shale gas fractures in the Sichuan Basin. The research findings and results provide important references and technical support for further exploration and development of marine shale gas in South China.