冀东黄柏峪—羊崖山地区太古宙岩浆作用和变质作用——SHRIMP锆石U-Pb定年

报道了冀东黄柏峪—羊崖山地区太古宙变质辉长岩、黑云斜长片麻岩、片麻状二长花岗岩、片麻状富钾花岗岩等不同类型变质岩浆岩(8个样品)的SHRIMP锆石U-Pb定年结果。首次发现3.1Ga二长花岗岩,黑云斜长片麻岩形成时代约为3.0Ga。变质辉长岩的侵入时代很可能为新太古代晚期,存在少量3.2~3.6Ga捕获锆石。几乎所有岩石样品都记录了约2.5Ga的变质锆石年龄。结合前人资料认为,(1)冀东地区新太古代晚期构造热事件十分发育,被认为与地幔软流圈上涌导致的岩浆板底垫托有关;(2)冀东地区中太古代以前的陆壳物质广泛分布,黄柏峪—羊崖山地区很可能存在一古老陆核。     

蒙大拿州Beartooth山脉北Snowy地块的太古代构造

位于蒙大拿州Beartooth山脉北西部的北Snowy地块主要是由七个太古代岩性单元组成:(1)Mouny Cowen眼球状花岗质片麻岩;(2)由大量长英质片麻岩、砂屑片岩、角闪岩和铁建造组成的副片麻岩系;(3)眼球状构造的花岗质凝灰岩;(4)千枚状Dauis Geeek片岩;(5)奥长花岗质片麻岩—角闪石岩杂岩;(6)Pine Greek推覆杂岩,为一具有闪岩核和两翼对称出现大理岩和石英岩的区域等斜构造;(7)上壳混合杂岩,由石英岩—闪岩组合和具有花岗质物质间层贯入上壳岩的非均质片麻岩组成。每个单元有其特征的岩性组合、变质级和构造样式。大多数单元之间的接触部位以糜棱岩(被认为是韧性断层的产物)和变质级的突变为标志。在四个构造作用最强的单元中,这些变化造成变质级的逆向和不连续增加。这些单元现在的轮廓最好解释为,在2.74Ga和2.56Ga前,变质期后,可能沿走向滑移断层和逆冲断层的构造拼合。从更大的范围看,这一地区位于怀俄明州北部两个截然不同地体的边界上(副片麻岩—Mount Cowan接触)。一个为东西的晚太古代侵入地体。另一个是西面的太古代变质上壳岩地体。NSB和Beartooth山脉的其它部分的关系表明,这个边界产生在晚太古代造山运动期间,与现代碰撞环境有许多相似性。     

Madras(马都拉斯)麻粒岩的稀土元素地球化学

印度南部 Tamil Nadu,Madras 地区典型紫苏花岗岩产地的太古代麻粒岩是由一套基性和酸性两种形式的正片麻岩组成的,并伴随有沉积变质片麻岩(孔兹岩系).紫苏花岗岩是一种主要的岩石类型。基性麻粒岩表现出一种具有明显富铁拉斑玄武岩的特点,伴随着稀土元素(REE)浓度的增加,并出现了铕(Eu)负异常.这些特点被认为是反映了辉石——斜长石组合在氧逸度(fo_2)低的条件下的低压分离结晶作用。超 Fe—Mg 质麻粒岩可能代表着这个过程的堆积物.酸性麻粒岩(紫苏花岗岩)一般是富 K_2O 的,而在大多数麻粒岩相地段占主要地位的酸性片麻岩则显然不同,K_2O 都低。然而,紫苏花岗岩中 REE 丰度具有在富 K 和贫 K 的两种太古代片麻岩中所观察到的整个范围。在这个地区大量前麻粒岩相钾质伟晶岩的出现,表明在原来钾含量较少的岩石组合中产生了钾质交代作用。微量元素产生了这样一个模式,即在麻粒岩相变质事件之前产生了酸性片麻岩的交代作用和局部熔融。这种事件的顺序是与地壳深部变质流体的成分的波动有密切的关系.     

冀北太古代花岗质片麻岩的成因

冀北是华北克拉通早前寒武纪变质基底的主要出露地区之一。分布于承德-滦平和赤城-张家口地区的新太古代花岗质片麻岩主要由英云闪长岩、奥长花岗岩、花岗闪长岩和二长花岗岩(TTGM)组成,构成了低钾、中钾和高钾钙碱性三个岩石化学系列。二长花岗质片麻岩的LA-ICP-MS锆石U-Pb和Lu-Hf同位素特征揭示其岩浆结晶年龄为2509±10Ma。全岩岩石化学、Sm-Nd同位素和锆石Lu-Hf同位素研究表明:(1)低钾钙碱性系列的岩石形成于拉班玄武质岩石的低度部分熔融;(2)中钾钙碱性系列岩石主要形成于玄武质岩石和杂砂岩的部分熔融,局部存在英云闪长质片麻岩的部分熔融;(3)高钾钙碱性系列的岩石形成于以高钾中酸性火山岩为主要成分的杂砂岩的部分熔融。结合近年来冀北早前寒武纪地质研究成果,这些太古代花岗质片麻岩全岩Sm-Nd同位素和锆石Lu-Hf同位素特征揭示~2.7Ga是本区太古代地壳的主要生长期。在新太古代发生了大规模的火山喷发,火山物质形成后不久发生部分熔融形成花岗质岩浆,接着发生变质、变形作用。这些花岗质片麻岩的形成与南美洲西海岸的构造-岩浆活动特征有类似之处,可能反映了太古代末期冀北地区从活动大陆边缘地壳增生、加厚到弧后伸展转化的动力学背景。     

清原太古代花岗岩-绿岩地体的常量和微量元素地球化学证据

目前公认的两个太古代基本岩石组合是花岗岩-绿岩和高级片麻岩。由于绿岩带不仅在地壳的早期形成和演化上具独特意义,而且蕴藏有极为丰富的金、铜、铁和镍等矿产,因此引起我国广大地质工作者的极大注意。我国太古代变质杂岩,很可能大部分都与高级片麻岩组合类似,而     

华北克拉通晚太古代末-古元古代初的岩浆事件及构造热体制

华北克拉通变质基底中广泛出露岩浆成因的正片麻岩。本文将华北克拉通分为11个变质地区,对其中新太古代末-古元古代初的正片麻岩的产状、岩性、形成时代进行了讨论。通过对这11个变质地区的对比可以看出,华北克拉通新太古代末-古元古代初的正片麻岩具有以下特征:(1)新太古代末-古元古代初的岩浆事件分布广泛,该期岩浆事件所形成的正片麻岩不仅在东部陆块、西部陆块广泛分布,而且在中部造山带也有广泛出露,在各变质地区该期的正片麻岩通常占变质基底总面积的70%以上;(2)该期岩浆事件主要集中在从2540Ma到2490Ma的50Ma期间。目前的年龄数据统计该期间形成的正片麻岩占2600Ma到2450Ma所形成的正片麻岩的75%;(3)该阶段形成的钠质片麻岩和钾质片麻岩在形成时间上几乎一致,在各变质地区不同成分的正片麻岩不具分带性。但钾质花岗岩在辽宁鞍山、辽西绥中、冀东秦皇岛和鲁西傲徕山分布相对集中;(4)该期岩浆事件与变质事件几乎同时发生,变质事件通常较岩浆事件晚10～15Ma,在有些地区几乎同时,表明岩浆事件和变质事件是同一构造热事件的产物;(5)该期岩浆事件所产生片麻岩的εHf(t)值绝大多数为正值,表明它们是有地幔物质加入的新生地壳再造的产物。综合以上特征,我们认为在华北克拉通新太古代末-古元古代初广泛的岩浆事件是地幔柱底侵导致的,该期广泛的岩浆事件造就了华北克拉通的基本形态。     

鞍山地区营城子古太古代片麻岩杂岩的识别与锆石U-Pb年代学研究

鞍山地区分布有始太古代-新太古代花岗岩杂岩,是研究早期地壳物质组成及其演化的经典地区之一.通过大比例尺岩性调查工作,新近在营城子识别出一套片麻岩杂岩和奥长花岗岩组合,为本区古老岩系的对比、构造格局恢复、太古代地壳形成与演化研究提供了新的依据和线索.片麻岩杂岩主要由条带状黑云斜长片麻岩、(脉状)奥长花岗质片麻岩以及黑云母片岩组成,呈不同规模的包体产出于细粒、均匀块状的奥长花岗岩之中.片麻岩杂岩的岩石组合以及复杂多变、明显不均一的岩石组构特征表明具有深熔混合岩的成因特点.SIMS锆石U-Pb定年表明,片麻岩杂岩中条带状黑云斜长片麻岩和黑云母片岩形成年龄分别为3312±14Ma、3304±7Ma和3324±7Ma～3235±14Ma,明确反映古太古代热事件,此外个别样品中存在3.68～3.60Ga和～3.47Ga继承锆石.细粒黑云奥长花岗岩的年龄为3.14～ 3.13Ga,与全区中太古代岩浆热事件一致.区域对比分析表明:营城子片麻岩杂岩的岩石组合、产状关系和年代学特征与东山杂岩和深沟寺杂岩十分相似,为古大古代(3.33 ～3.24Ga)深熔作用的产物.营城子片麻岩杂岩是鞍山地区另一个保留有古老锆石信息和太古宙早期地壳岩石的地质体.     

北大别片麻岩的超高压变质证据——来自锆石提供的信息

本文对北大别片麻岩锆石中矿物包体及年代学进行了研究,首次发现了北大别片麻岩的超高压变质作用证据。结合阴极发光图像和同位素定年,片麻岩锆石中矿物包体组合至少可分出三期:(1)原岩岩浆矿物组合,即斜长石、黑云母、石英和磷灰石;(2)超高压变质矿物组合,即金刚石、石榴子石和金红石等;(3)麻粒岩相退变质矿物组合,如透辉石等。其中,金刚石和石榴子石主要以包体形式被包裹于透辉石中,而透辉石是北大别麻粒岩相退变质阶段形成的代表性矿物。锆石SHRIMP U-Pb定年结果表明,北大别片麻岩的峰期变质时代和麻粒岩相退变质时代分别为218±3Ma和199±10Ma。这些证明北大别片麻岩,如同其中的榴辉岩一样,经过了印支期超高压变质作用。     

华北麻粒岩相岩石的主要特征及今后研究中值得注意的几个问题

华北前寒武纪麻粒岩与国外同类组合相比有特殊性,如(1)具面状分布的特点;(2)麻粒岩类型缺少斜长岩-淡色辉长岩组合以及下部堆晶相辉长岩组合,灰色片麻岩比例少,并普遍受到钾质交代;(3)多为不亏损型麻粒岩,未发现熔融残留型麻粒岩;(4)变质压力为低—中压过渡型,堇青石在变质沉积岩中普遍存在;(5)华北克拉通经历了多期麻粒岩相变质作用。这些特征对于深入研究华北麻粒岩的成因、下部地壳的性质以及克拉通的形成和演化都是必须加以考虑的。     

前寒武纪地球动力学(Ⅶ):早期大陆地壳的形成与演化

冥古宙到太古宙大陆地壳主要由花岗质片麻岩区和绿岩带构造单元组成。大量的研究表明,以花岗质岩石出现为标志的大陆地壳最早的碎屑锆石记录为约4.4Ga,最早的英云闪长质-花岗闪长质片麻岩形成于约4.03Ga,最早的绿岩带层序形成于约3.8Ga。冥古宙到始—古太古代时期的花岗质片麻岩区主要由英云闪长质-奥长花岗质-花岗闪长质片麻岩组成(TTG片麻岩),中—新太古代,尤其是新太古代晚期TTG片麻岩仍然为花岗质片麻岩区的主要岩石组成,但是花岗质片麻岩的成分出现了明显的多样化趋势,最明显的标志就是出现了大量的花岗闪长岩-二长花岗岩-碱长花岗岩组合。绿岩带的组成较为复杂,早期科马提岩、拉斑玄武岩等铁镁质火山岩占主导地位,组合有BIF等沉积层序,尤其是科马提岩的出现标志着高温地幔岩浆作用占主导作用。而晚期绿岩带科马提岩占的比重已经明显较少,大量出现拉斑玄武质-钙碱性玄武质到英安质火山岩和副变质沉积层序,局部出现类玻安岩、埃达克岩的变质火山岩记录。地球动力学体制研究表明,冥古宙到古太古代以地幔柱构造体制占主导地位,从始太古代到古太古代(3.0Ga)地幔柱活动和地幔对流使岩石圈不断加厚。在地幔对流沉降部位,由于地幔对流的拖曳使其铁镁质地壳逆冲堆垛并不断增厚,其深部发生麻粒岩相-榴辉岩相变质、部分熔融形成初始的大陆地壳花岗质岩石,并孕育了早期高温状态的板块热俯冲。中太古代晚期和新太古代初期形成了以榴辉岩为标志的类现代板片俯冲的构造体制,新太古代末期尽管地幔柱构造体制在局部仍起重要作用,但是类现代板片俯冲构造体制已经成为这一时期主导的动力学体制。     

地史早期岩石中的铅锌演化--狼山-渣尔泰山中元古代铅锌成矿的物质基础

以中国内蒙古狼山一渣尔泰山中元古代SEDEX型铅．锌成矿带为例，研究了该区从太古代到中元古代地壳岩石的铅锌含量和变化关系以及与成矿的关系。研究发现，从早到晚，岩石SiO2和K2O含量升高，铅含量也与二者同步增加；FeO、MgO、CaO及Na20含量呈下降趋势，锌含量也同步降低。在太古代时，岩石的Zn／Pb比值一般〉8，中元古代时这一比值降低为2～4。矿石的Zn／Pb比值与基底岩石Zn／Pb比值具有很好的一致性。铅锌这种随时间的变化与中元古代铅的暴发性成矿及大规模铅锌共生矿床的形成是同步的，说明基底岩石中的铅和锌是该成矿带SEDEX矿床成矿的物质基础。     

Precambrian crustal contribution to the Variscan accretionary prism of the Kaczawa Mountains (Sudetes,SW Poland): evidence from SHRIMP dating of detrital zircons

SHRIMP dating of detrital zircons from sandstones of the Gackowa Formation (Kaczawa Complex, Sudetes, SW Poland) indicates input from late (550–750 Ma) and early Proterozoic to Archaean sources (∼2.0–3.4 Ga, the latter being the oldest recorded age from the Sudetic region). These dates preclude within-terrane derivation from seemingly correlatory acid volcanic rocks of early Palaeozoic age. Rather, they indicate provenance from Cadomian and older rocks that currently form part of other, geographically distant terranes; the most likely source identified to date is the Lusatian Block in the Saxothuringian Zone. Hence, the Gackowa Formation may be late Proterozoic rather than early Palaeozoic in depositional age, possibly coeval with the late Proterozoic (pre-Cadomian) greywackes of Lusatia, being subsequently tectonically interleaved with early Palaeozoic volcanic rocks into the Kaczawa accretionary prism during the Variscan orogeny. However, correlation with the lithologically similar early Ordovician Dubrau Quartzite of Saxothuringia, and so assignation to the early Paleozoic (post-Cadomian) rift succession deposited at the northern margin of Gondwana, cannot yet be precluded.     

辽东半岛早元古宙地壳的演化

辽东半岛早元古代岩层可以划分为三个演化阶段。早期阶段,在硅铝壳内的滑动面上裂开而造成宽度远较现存早元古代岩层分布为宽的裂谷式地槽,最突出的特点是构成了优冒地槽同时异相并存的局面。中期阶段层状的堆积物是由大石桥岩组与盖县岩组所构成,前者为厚约4km的厚层状碳酸盐岩,后者为厚度大于5km的泥砂质岩石。晚期阶段、局限于南部局部地区,由石英砂岩、石英岩、长石石英砂岩组成,厚度大于10km。由同位素年龄资料所知,早元古宙地槽下限为2300—2500Ma,上限可能为1700Ma,2000Ma前后发生过一次中等程度地质     

辽西早白垩世义县组火山夺的起源及壳幔相互作用

对燕山造山带辽西早白垩世义县组火山岩的Nd,Sr,Pb同位素分析，作者认为义县组火山岩起源于岩石圈地幔的部分熔融，岩浆在上侵过程中发生了结晶分异和同化混染作用，即AFC过程。与新生代汉诺坝玄武岩中的中生代镁铁质麻粒岩捕虏体和太古代片麻岩对比研究，发现义县组火山岩与这些镁铁质麻粒岩捕虏体有许多地球化学相似之处，而与长英质麻粒岩捕虏体和太古代各种片麻岩差别较大。作者认为早白垩世燕山板内造山带发生了强烈的岩石圈伸展作用，辽西义县组火山岩和汉坝新生代玄武岩中的镁铁质麻粒岩捕虏体均为这一构造背景下的产物，它们属于幔源岩浆喷发与大规模玄武zh质岩浆底侵作用形成的“同质异相体”。     

Exposed Cross-section of the Archaean Lower Crustin the Shanxi-Hebei-Inner Mongolia Border Region: Problems and Prospects

The Archaean lower crust represented by granulite facies rocks, which is rare in China, is found to be exposed in the Shanxi-Hebei-Inner Mongolia border region. Studies of the regional structure and deformation and metamorphism of the region indicate that there occurred at least two phases of deformation and metamorphism in the region. Early-phase nearly E-W-directed deformational structure is well preserved in the Zhangjiakou-Xuanhua area. Observations of the features of the geological structure from north to south (in the Hengshan metamorphic terrain) have revealed a possible exposed cross-section through the Archaean lower crust. The structure was superimposed by a NE-SW-trending high-temperature ductile shear zone in the Datong area in the late phase, thus reworking the Archaean sequence.     

华北板块北缘东段早前寒武纪稀土元素演化特征

通过对区内早太古宙深变质地体、晚太古宙花岗岩-绿岩地体,晚太古-早元古宙优地槽和火山岛弧各类变质岩稀土元素的研究,三个时期的稀土元素具大致相似的演化特征,不同时期相同的岩石类型的稀土配分型式也大致相似,反映了它们有着相同源岩。但是,它们又在稀土丰度、Eu异常和轻、重稀土分离程度方面表现出某些差异,表明本区在早前寒武纪的不同时期、不同构造环境中地壳成分的不均一性。不同岩石类型稀土配分的多样性,说明岩浆源不同,至少有超镁铁质、镁铁质和安山质或英云闪长岩-奥长花岗岩三种岩浆源。     

Geochronological evidence for late‐Grenvillian magmatic and metamorphic events in central Taimyr,northern Siberia*

U–Th–Pb analyses of zircons from six granites and one metasediment collected in the accretionary Central belt of Taimyr, Arctic Siberia, demonstrate that Neoproterozoic (c. 900 Ma) granites intrude late Mesoproterozoic/early Neoproterozoic amphibolite facies metamorphic rocks. This is the first time in the Mamont–Shrenk region that Neoproterozoic ages have been recognized for these lithologies, previously thought to be Archaean/Palaeoproterozoic in age. The Mamont–Shrenk Terrane (MST) represents a Grenvillian age (micro?) continent intercalated with younger Neoproterozoic ophiolites during thrusting and accreted to the northern margin of the Siberian craton sometime before the late Vendian. Basement to the MST may have been derived from the Grenvillian belt of east Greenland. Viable tectonic reconstructions must allow for an active margin along northern Siberia (modern day coordinates) in the middle Neoproterozoic.     

Crustal contamination as an indicator of the extent of early Archaean continental crust: Pb isotopic evidence from the late Archaean gneisses of West Greenland

Ph isotopic analyses are reported for 119 samples of late Archaean (ca. 3000-2800 Myr) calc alkaline orthogneisses and associated anorthosites from southern West Greenland. Over most of the area. $\text{Pb}\text{Pb}$ whole rock isotope systematics indicate derivation of the magmatic precursors of the gneisses and anorthosites from a source region with a typically mantle-type $\text{U}\text{Pb}$ ratio (μ₁ value of 7.5) at. or shortly before, ca. 3000-2800 Myr ago. In contrast, in the Godthaabsfjord region, late Archaean Nûk gneisses and associated anorthosites were emplaced into or through early Archaean (ca. 3700 Myr) Amîtsoq gneisses, and crystallised with variable proportions of two isotopically distinct types of Pb which commenced their respective crustal developments at ca. 3000-2800 Myr and at ca. 3700 Myr ago. Isotopic and other geochemical constraints demonstrate that Nûk gneisses and their temporal equivalents were not produced by reworking or melting of Amîtsoq gneisses. Mixing of early and late Archaean Pb results from contamination of the magmatic precursors of Nûk gneisses and anorthosites (characterised by mantle-type Pb at time of emplacement) with ancient, unradiogenic Pb derived from ca. 3700 Myr-old Amîtsoq-type continental crust invaded by the Nûk magmas. The contaminant is considered to be a trace-element enriched fluid phase released from dehydrating older continental crust during progressive burial and heating by emplacement of calc alkaline magmas in the late Archaean ‘accretion differentiation superevent’. This was followed by mixing of the released fluids with younger Nûk magmas.Pb isotopic compositions of late Archaean gneisses and anorthosites outside the Godthaabsfjord region provide no evidence for the presence of early Archaean Amîtsoq-type continental crust in southern West Greenland in areas more than a few tens of km outside the known outcrop of Amîtsoq gneisses. We suggest that early Archaean crust does not exist at depth in late Archaean areas with undisturbed Pb-isotope systematics, either in Greenland or elsewhere in the North Atlantic craton.Pb-isotope evidence for crust magma interaction, involving selective extraction of certain trace elements by a fluid phase from wall rock and subsequent mixing between magma and contaminant fluid, provides a powerful tool for detection, sub-surface ‘mapping’, and geochronological and geochemical characterisation of deep, ancient continental crust.     

Meso–Neoarchaean crustal evolution of the Bundelkhand Craton,Indian Shield: new data from greenstone belts

ABSTRACT

The Mauranipur and Babina greenstone belts of the Bundelkhand Craton are formed of the Central Bundelkhand greenstone complex (CBGC). This complex represents tectonic collage which has not been previously studied in depth. The purpose of this study is to contribute to the understanding of the main features of the Archaean crustal evolution of the Bundelkhand Craton. The CBGC consists of two assemblages: (1) the early assemblage, which is composed of basic-ultramafic, rhyolitic–dacitic, and banded iron formation units, and (2) the late assemblage, which is a felsic volcanic unit. The units and assemblages are tectonically unified with epidote–quartz–plagioclase metasomatic rocks formed locally in these tectonic zones.

The early assemblage of the Mauranipur greenstone belt is estimated at 2810 ± 13 Ma, from the U–Pb dating (SHRIMP, zircon) of the felsic volcanics. Also, there are inherited 3242 ± 65 Ma zircons in this rock. It is deduced that this assemblage is related to early felsic subduction volcanism during the Mesoarchaean that occurred in the Bundelkhand Craton.

Zircons extracted from metasomatic rocks in the early assemblage’s high-Mg basalts show a concordant age of 2687 ± 11 Ma. This age is interpreted as a time of metamorphism that occurred simultaneously with an early accretion stage in the evolution of the Mauranipur greenstone belt.

The felsic volcanism, appearing as subvolcanic bodies in the late assemblage of the Mauranipur greenstone belt, is estimated to be 2557 ± 33 Ma from the U–Pb dating (SHRIMP, zircon) of the felsic volcanic rocks. This rock also contains inherited 2864 ± 46 Ma zircons. The late assemblage of the Mauranipur greenstone belt corresponds with a geodynamic setting of active subduction along the continental margin during Neoarchaean.

The late assemblage Neoarchaean felsic volcanic rocks from the Mauranipur and Babina greenstone belts are comparable in age and geochemical characteristics. The Neoarchaean rocks are more enriched in Sr and Ba and are more depleted in Cr and Ni than the Mesoarchaean felsic volcanic rocks of the early assemblage.

Through isotopic dating and the geochemical analysis of the volcanic and metasomatic rocks of the CBGC, this study has revealed two subduction–accretion events, the Meso–Neoarchaean (2.81–2.7 Ga) and Neoarchaean (2.56–2.53 Ga), during the crustal evolution of the Bundelkhand Craton (Indian Shield).     

Emanation-Sedimentary Metallogenic Series and Models of the Proterozoic Rift in the Kangdian Axis

The Kangdian axis basement can be divided into two tectonic layers. The lower tectonic layer is the crystalline basement which is made up of the Archaean Dibadu Formation and early Proterozoic Dahongshan Group. The former is a kata-metamorphic basic volcano-sedimentary formation of the old geosyncline (old continental nucleus), and the latter is a medium-grade metamorphosed alkali-rich basic volcanic (emanation)-sedimentary formation of the Yuanjiang-Dahongshan marginal rift. They are in disconformable contact. The upper tectonic layer is the folded basement, and made up of the middle-late Proterozoic Kunyang Group. It is the result of Dongchuan-Yuanjiang intercontinental rifting with discordant contract with the underlying and overlying strata. Along with the evolution of Proterozoic from early to late, four types of emanation-sedimentary deposits in the Kangdian axis rift were formed in turn: (1) emanation-sedimentary iron-copper-gold deposits related to basic volcanic rocks in the Yuanmou-Dahongshan