Giant Mineral Deposits and Their Geodynamic Setting in the Lanping Basin, Yunnan, China

There are giant mineral deposits, including the Jinding Zn-Pb and Baiyangping Ag-Co-Cu, and otherimportant mineral deposits (e.g., Baiyangchang Ag-Cu, Jinman Cu deposits, etc.) in the Lanping Mesozoic-Cenozoic Basin, Yunnan Province, China. The tabular ore-bodies and some veins hosted in terrestrial clastic rocks of the Mesozoic-Cenozoic age and no outcropping of igneous rocks in the giant deposits lead to the proposal of syngenetic origin, but the giant mineral deposits are not stratabound (e.g. MVT, sandstone- and Sedex-type). They formed in a continental red basin with intense crust movement. The mineralization is controlled by structures and lithology and occurs in different strata, and no sedimentary nature and no exhalative sediments are identified in the deposits. The deposits show some relations with organic matter (now asphalt and petroleum) and evaporates (gypsum). The middle-low-temperature (mainly 110℃ to 280℃) mineralization took place at a depth of about 0.9 km to 3.1 km during the early Himalayan (58 to 67 Ma). The salinity of ore-forming fluids is surprisingly low (1.6% to 18.0 wt% (NaCl)eq). Affected by the collision of the Indian and Eurasian plates, the mantle is disturbed under the Lanping Basin. The large-scale mineralization is closely linked with the geodynamics of the crust movement, the mantle and mantle-flux upwelling and igneous activity. Giant mineral deposits and their geodynamic setting are unique in the Lanping Basin.

Cenozoic evolution of tectono-fluid and metallogenic process in Lanping Basin, western Yunnan Province, Southwest China: Constraints from apatite fission track data

Since the Mesozoic, abundant metal and salt deposits have been formed in the Lanping Basin, western Yunnan Province, Southwest China, constituting a well-known hydrothermal ore belt in China. Most of the deposits are meso-epithermal hydrothermal deposits. This paper preliminarily deals with the mineralization ages of hydrothermal deposits in the Lanping Basin by using the apatite fission track method, and integrates the spatial distribution of the deposits and their regional geological backgrounds, to give the preliminary viewpoints as follows: (1) the apatite fission track ages acquired range from 19.9 Ma to 52.8 Ma, much younger than those of their host strata, so they may be considered to be mineralization ages, which represent the late mineralization period; (2) the apatite fission track ages tend to become younger from the west to the middle of the basin, indicating that the latest evolution of tectono-fluid and/or metallogenic processes of the middle basin ended later than that in the west; (3) in the Paleogene, most of the Cu deposits were formed in the western part of the basin; (4) the major metallogenic processes occur between the Paleogene and the Neogene, because the eastern and western edges of the basin were subducted into and collided with its bilateral continental blocks, respectively, and the central fault was strongly activated, which led to the processes of large-scale ore-forming fluids, and their differentiation and transport because of the variation of their physical and chemical properties. Having been squeezed and uplifted, the Lanping Basin became an intermontane basin that contains many kinds of fluid traps resulting in the formation of different types of ore deposits (for example, Pb-Zn, Cu, Ag) of different scales in the middle of the basin. Simultaneously, the fluids with volatile elements such as Hg, Sb and As were transported upwards along the central fault system and diffused into its subordinate fractures, thus leading to the metallogenic processes of Hg, Sb and As in the eastern composite anticline of the Lanping Basin; (5) and later, these ore deposits experienced reformation and oxidization. To summarize,deep giant faults were active in the basin, and metallogenic processes were constrained by the evolution of tectono-fluids in the Lanping Basin. Simultaneously, the occurrence of the metallogenic processes made the nature of fluid and the structural environment change, which led to returning and recycling of the fluids. Multi-stage and zonational metallogenic processes are the characteristics of the ore deposits in the Lanping Basin.

^(40)Ar-^(39)Ar Dating of Quartz from Ore in the Baiyangping Cu-Co Polymetallic Ore-Concentrated Area, Lanping Basin, Yunnan

Ar- 39Ar fast neutron activation age spectrum of quartz in ore collected from the Baiyangping Cu-Co polymetallic ore-concentrated area, Lanping Basin, is saddle-shaped. The plateau age, minimum appearance age and isochron age shown on the spectra are 56.53± 0.43 Ma, 55.52± 1.78 Ma and 55.90± 0.29 Ma respectively. The age data are consistent with each other within 1σ uncertainties. Because the given initial 40Ar/ 36Ar value of 294.7± 1.14 is very close to Nier’s value ( 295.5±5), both plateau and isochron ages may be considered as the forming time of quartz. So the age of 55.90- 56.53 Ma represents the forming age of ore deposits. It is obvious that the ore deposits were formed during the Early Himalayan period.

Basin Fluid Mineralization during Multistage Evolution of the Lanping Sedimentary Basin,Southwestern China

The Lanping sedimentary basin has experienced a five-stage evolution since the late Paleozoic： ocean-continent transformation （late Paleozoic to early mid-Triassic）; intracontinental rift basin （late mid-Triassic to early Jurassic）; down-warped basin （middle to late Jurassic）; foreland basin （Cretaceous）; and strike-slip basin （Cenozoic）. Three major genetic types of Ag-Cu polymetallic ore deposits, including the reworked hydrothermal sedimentary, sedimentary-hydrothermally reworked and hydrothermal vein types, are considered to be the products of basin fluid activity at specific sedimentary-tectonic evolutionary stages. Tectonic differences of the different evolutionary stages resulted in considerable discrepancy in the mechanisms of formation-transportation, migration direction and emplacement processes of the basin fluids, thus causing differences in mineralization styles as well as in genetic types of ore deposit.

滇西兰坪盆地膏盐微量元素、同位素地球化学特征及意义

滇西兰坪盆地中多数金属矿床伴生大量膏盐体,为了探讨膏盐体与金属成矿关系,对膏盐体进行了微量元素和同位素地球化学分析。发育在云龙组中呈层状黑色石膏稀土总量,δEu(0.87)和δCe(0.95),^(87)Sr/^(86)Sr(0.708629~0.710189),δ^(34)S_(V-CDT)(9.6‰~+11.9‰)与区域云龙组地层地球化学特征相近;分布在云龙组地层中呈蘑菇状、指状侵入的块状石膏的稀土总量,δEu(0.65)和δCe(0.85),^(87)Sr/^(86)Sr(0.707695~0.708127),δ^(34)S_(V-CDT)(+12.6‰~+15.4‰)与晚三叠世三合洞组碳酸盐岩的地球化学特征相近。结合微量元素和同位素地球化学分析,兰坪盆地的Sr、Cu、Pb和Zn等成矿元素主要来源于热卤水对地层的淋滤和萃取,成矿元素S主要为沉积地层中的硫酸盐热化学还原的产物。

云南兰坪县河西锶矿床地质特征及成矿条件

兰坪县河西锶矿区含矿岩性为一套碳酸盐岩,矿体主要受断裂控制。通过半封闭还原法分析SrSO_(4)含量93.37ω%。形成于干旱气候的开阔海相沉积环境。通过硫同位素测定,锶来源于石钟山组内,后经热液改造富集成矿,矿床类型属沉积-热液型矿床。

深部铅锌热液流体作用下的原油地球化学特征

中国南方盆地深部热液流体活跃区分布广泛,热液流体类型各有不同,滇西北兰坪地区幔源铅锌热液成矿流体尤为显著,形成了典型的超大型陆相沉积浅成矿床,其中古油气藏遗迹明显,深部铅锌热液流体活动对生烃及油藏热蚀变的影响显著。通过分析热蚀变后铅锌矿中伴生原油及固体沥青中生物标志物、烃类及杂环化合物的地球化学特征,发现随着深部热液流体作用增强,生物标志物(如正构烷烃、甾烷、藿烷等)相对含量逐渐降低,未分离复杂混合物(UCM)相对含量逐渐增加,弱偶碳数优势明显(CPI≤1.0),多环芳烃(PAHs)相对含量逐渐降低,而链状苯基化合物(如联苯)与含S化合物(如噻吩类)相对含量逐渐增加。样品不存在明显的生物降解、蒸发分馏、硫酸盐热化学还原(TSR)及原油裂解等次生作用。兰坪地区铅锌矿中伴生原油和沥青的分子地球化学特征及其特殊的变化规律,可能是由于沉积有机质或古油藏与富催化剂的幔源铅锌热液流体发生热液催化反应导致的。本研究揭示了深部热液流体作用和分子地球化学特征的耦合关系,识别并提出了热液流体作用下杂环化合物形成的机制和原油热蚀变的指标。

滇西北兰坪盆地金满-连城脉状Cu多金属矿床Cu-S同位素特征及其指示意义

兰坪盆地西缘发育一系列脉状Cu多金属矿床,成矿独具特色,它们的成矿流体普遍存在大量富CO_(2)流体包裹体,在整个兰坪盆地罕见,显著区别于世界上已知的各类贱金属矿床。本研究测定了兰坪盆地西缘两个代表性脉状Cu矿床(金满Cu矿床和连城Cu-Mo矿床)主成矿阶段黄铜矿和黝铜矿的Cu-S同位素组成,探讨其成矿物质来源和成矿机制。结果表明,金满Cu矿床黄铜矿的δ^(65)Cu值变化较大(-3.62‰~0.48‰),δ^(34)S值为-4.0‰~12.1‰,可能与多期流体活动、成矿物质多来源有关,成矿主要与深部岩浆活动有关,成矿晚期有地层物质的加入。连城Cu-Mo矿床主成矿期黄铜矿δ^(65)Cu值为-0.31‰~2.12‰,δ^(34)S值为-3.6‰~1.4‰,暗示成矿与深部岩浆作用有关。

兰坪-思茅盆地宁洱地区新生代玄武岩地球化学特征及意义

宁洱新生代玄武岩主要分布于宁洱县城与通关周围,玄武岩覆盖在下白垩统之上,主要由橄榄玄武岩及橄斑玄武岩组成,具气孔构造,斑状结构,含有较多的斜长石斑晶。宁洱新生代玄武岩为碱性玄武岩,其特征为大离子亲石元素Ba和高场强元素Nb、Ta、Zr、Th较为富集,Ti、Al含量较高,Si含量低,轻重稀土元素分异较明显,表现出明显的Eu正异常,δEu平均值为1.34。宁洱玄武岩的地球化学特征显示其来自于陆内裂谷环境,岩浆来自于富集地幔,分离结晶作用较弱且几乎未受到地壳的混染作用。宁洱玄武岩形成于更新世时期,是兰坪—思茅盆地中轴构造活动剧烈导致新生代活动断裂相互错动,活跃岩浆迅速溢出地表的产物。区域内新生代的断裂构造具有裂谷的性质,可能处于裂谷形成的早期阶段。

滇西兰坪盆地构造体制和成矿背景分析

大规模成矿作用的地质构造背景是国内外矿床学界普遍关注的重大问题。文章从盆地整体着眼 ,从盆地构造_沉积_岩浆_变质作用过程着手 ,通过盆地内地质、地球物理和遥感等事实分析了滇西兰坪盆地的构造体制和成矿背景。兰坪盆地在古特提斯构造基础上发展起来 ,近南北向盆缘超岩石圈断裂和盆中央穿壳断裂及近东西向隐伏构造共同控制了盆地的动力过程 ,中_新生代经历了印支期裂谷、燕山期拗陷及喜马拉雅期走滑拉分的性质演变。受印度板块与欧亚板块碰撞制约 ,板内构造体制下的深大断裂和岩浆活动、幔流上涌、地层中不整合及壳幔相互作用等所体现的大陆地壳强烈运动是兰坪盆地的成矿基本地质背景。

滇西沘江流域水体中重金属元素的地球化学特征

通过测定流经兰坪金顶铅锌矿区的沘江水体中Pb、Zn、Cd、As的含量和底泥中重金属元素的化学形态的含量,分析了重金属元素的分布和化学形态的变化。结果表明,沘江水遭到了Cd污染,底泥已经成为重金属元素的蓄积库,以国家土壤环境质量标准(Ⅲ级)衡量,Pb、Zn、Cd和As分别超标3.4倍、15.8倍、106倍和2.6倍。沘江水中重金属元素含量的峰值在矿山附近的下游,而底泥中重金属元素的峰值在矿山下游30～50km的地方,矿业活动、水流变缓、pH等水体环境条件的变化都能影响水和底泥中重金属元素的含量。底泥中的Pb以碳酸盐结合态为主,Zn和Cd以铁锰氧化物结合态为主,而As以残渣态为主。Pb、Cd、Zn三种元素的环境有效态含量比较高,对沘江流域生态环境具有潜在的巨大的危害。

兰坪—思茅盆地砂页岩中铜矿床同位素地球化学

兰坪—思茅中新生代盆地中的铜矿床 ,主要产于由砂岩、粉砂岩和页岩组成的含盐红色碎屑岩建造中。对矿床的同位素组成研究表明 :成矿溶液主要来自大气降水 ,矿化和蚀变作用是在水 /岩比值较低的体系中进行的 ;铅来自赋矿的沉积岩与基底岩石的混合 ;硫、碳和硅则具有多来源的特性。矿床地质特征和同位素组成特点表明 ,所研究的铜矿床与典型砂页岩型铜矿床存在显著差异 ,而与一些地热区的矿化作用相似。说明研究区砂页岩中的铜矿床具有特殊的成矿机理 ,即在经历了沉积成岩作用发生矿质初步聚集后又通过陆相喷流作用而形成工业矿床的。

云南勐野井钾盐矿床石盐中包裹体特征及其成因的讨论

本文通过对包裹体(包括单体和集合体)形态分类、均一温度以及温度升高时包裹体的溶解、结晶和气化现象的研究,认为云南勐野井钾盐矿床石盐中的包裹体是在三个阶段即蒸发沉积阶段、成岩阶段和成者期后形成的。蒸发沉积阶段可以进一步分为盐湖和干盐湖期。

兰坪盆地新生代碎屑岩地球化学特征及其对物源制约

兰坪盆地的新生代地层,包括勐野井组、等黑组、宝相寺组、金丝厂组和三营组等,岩性有砂岩、泥岩和砾岩。由于盆地内部断层纵横,新生代地层的横向对比比较困难,研究揭示新生代地层的物源对于恢复盆地的岩相古地理环境、探讨盆地演化与构造演化的关系等具有重要地质意义。根据砂岩、泥岩和砾岩胶结物的La/Th、La/Yb、Cr/Th、K/Rb、K/Th、Zr/Hf、Th/Sc、U/Th比值以及δCe和δEu等地球化学参数并结合沉积相的研究成果,可以看出兰坪盆地新生代沉积物存在三种物源组分:即深源卤水、基性-超基性岩和长英质岩石。金顶地区存在长英质岩石、基性-超基性岩和深源卤水三种物源混合的现象,啦井地区则存在长英质岩石、基性-超基性岩物源的混合。河湖相碎屑岩的Cr/Co比值可以指示物源区的距离远近,这个比值越小则物源区距离越大。

兰坪—思茅盆地砂页岩中铜矿床成矿物质来源研究

兰坪—思茅中、新生代盆地砂页岩中铜矿床的微量元素特征、稀土配分型式以及硫、铅、碳、氧、氢、硅等同位素组成等表明 ,成矿金属物质、硫和碳 ,既有来自赋矿岩石 (包括火山岩 ) ,又有来自基底岩石 ,同时还有深部物质的参与。成矿溶液主要来自大气降水 ,矿化和蚀变作用是在水 /岩比值较低的体系中进行的。

云南兰坪—思茅盆地勐野井钾盐矿床物质组分对成因的指示

云南兰坪—思茅盆地勐野井钾盐矿床是我国目前唯一的古代固体钾盐矿床。长期以来一直认为该矿床为海源陆相成因,也有人提出成矿物质还有其他来源,但并未给出确凿的证据。为了查明该矿床的物源及成因,本文采用XRD、ICP-MS、电子探针(EPMA)和显微镜等方法对云南江城勐野井钾盐矿床物质组分进行研究,并在此基础上,对矿床的成因进行剖析,指出成矿物质来源于两个方面。一为海水。微量元素Br在勐野井组盐层中的均值为578×10-6,远大于200×10-6,指示海源;同时在底板扒沙河组石英砂岩中存在少量海相矿物——海绿石。二为深部热液。勐野井组灰绿色泥岩中存在大量富含钴镍的黄铁矿;其次,盐层裂隙的充填物出现含钴镍的羟碳钴镍石;同时在扒沙河组砂岩中普遍见到含铜矿物——蓝铜矿和孔雀石等。由于该矿床地处强烈构造活动带,这些富含Cu、Co、Ni的矿物指示,Cu、Co、Ni等金属元素来源于深部热液。因此,云南勐野井钾盐矿床除海水提供成矿物质外,深部热液亦为矿床的形成提供了重要物源。

云南兰坪盆地喜马拉雅期碱性岩^(40)Ar/^(39)Ar年龄及地质意义

对侵位于云南兰坪中新生代红层盆地中的碱性岩进行了Ar_Ar同位素定年 ,获得永平卓潘碱性杂岩体的侵入年龄为 36 .70Ma,巍山莲花山碱性石英二长斑岩的侵入年龄为 38.81Ma。兰坪盆地的构造演化受控于古特提斯的闭合及印度与亚洲大陆碰撞的造山作用 ,盆地经历了陆内裂谷、拗陷盆地和走滑盆地 3个阶段的发育过程。喜马拉雅期盆地处于走滑拉分阶段 ,可分为 4个构造幕 ,碱性岩主要在第 1构造幕期间侵入。盆地中的碱性岩体是青藏高原东缘总体呈NW走向的金沙江红河巨型富碱侵入岩带的组成部分。金沙江红河断裂带经历由转换压扭变形(42～ 2 4Ma)到转换张扭变形 (2 4～ 16Ma)、再到东西向伸展 (<16Ma)的过程 ,兰坪盆地的碱性岩发育于转换压扭变形期间。

滇西北兰坪盆地白秧坪多金属矿床流体包裹体研究

白秧坪多金属矿床位于滇西兰坪中-新生代沉积盆地中北部,是著名三江成矿带内新近发现的重要矿床之一。碳酸盐矿物染色法岩相学和矿相学研究表明白秧坪多金属矿床成矿期早阶段共生组合矿物为闪锌矿+方铅矿+白云石+石英±含Ag矿物±含Cu矿物,方解石主要为成矿期晚阶段产物。闪锌矿及与其共生脉石矿物(白云石、石英)中流体包裹体多呈米粒状、椭圆状、负晶形以及不规则状,以孤立产出的原生包裹体为主。流体包裹体显微测温以及激光拉曼探针分析表明,成矿流体为H2O-NaCl-CaCl2流体体系,盐度峰值范围为22.00%～25.00%NaCleqv,成矿温度多数集中在110.0～180.0℃之间,密度大于1.00g.cm-3。该矿床属于低温、高盐度、中等密度热液铅锌多金属矿床。矿床成矿压力介于28.02～70.64MPa之间,成矿深度范围在1.04～2.62km,形成深度较浅。成矿流体始终处于相对还原环境,金属离子和还原硫可能共存于同一流体系统,由于物理化学条件的改变发生沉淀而形成矿床。结合矿床产出背景、矿质来源、控矿构造等因素,白秧坪多金属矿床具有密西西比河谷型(MVT)成矿流体特点。

兰坪盆地大型矿集区多金属矿床的铅同位素组成及铅的来源

滇西兰坪中、新生代陆相盆地中蕴藏有金顶超大型铅锌矿床、白秧坪大型银矿床及羊拉、金满等一系列大、中型铜矿床 ,矿点、矿化点星罗棋布 ,为一成矿时代新、矿床规模大、矿床种类丰富的大型矿集区。分布于盆地边缘的矿床与火山活动有一定关系 ,盆地内部的矿床产于中、新生代沉积岩中。铜矿床沿澜沧江深大断裂带东侧分布 ,向东至盆地中部 ,为铅锌银分布区 ,再向东出现汞锑砷矿化。该矿集区不同矿床的铅同位素组成及铅的来源 ,可分为三种类型 ,①金顶超大型铅锌矿床以具有低同位素比值的铅为主 ,铅的主体来源相当于下地壳铅 ,整个矿床的铅为下地壳铅与盆地沉积岩铅的混合铅 ;②金满铜矿床及盆地内其它铜铅锌矿床的铅来自盆地沉积岩 ;③位于盆地边缘的羊拉铜矿床 ,早期热水沉积成矿阶段铅的来源与二迭系玄武岩铅一致 ,为幔源铅 ,晚期热液成矿阶段铅来自地壳重熔型岩浆作用。

滇西兰坪盆地多金属矿床碳、氧、氢同位素组成及其地质意义

兰坪盆地多金属矿床碳、氧和氢同位素组成特征表明,成矿流体中的CO2源自海相碳酸盐岩(或蚀变海相碳酸盐岩)的热解作用和沉积有机物的氧化作用或脱羧基作用;成矿流体为古大气降水在一定地质条件下与盆地和基底岩石发生水岩作用而形成的盆地热卤水,其中金顶铅锌矿床的成矿流体尚有变质水的混入。这表明盆地内多金属矿床的成矿物质应源自地壳(基底和盆地地层),喜马拉雅期盆地周缘碱性岩浆活动对盆地内多金属矿床的成矿作用贡献是间接的,沉积有机物直接参与了成矿作用。