Paleozoic multiple accretionary and collisional tectonics of the Chinese Tianshan orogenic collage

Subduction-related accretion in the Junggar–Balkash and South Tianshan Oceans (Paleo-Asian Ocean), mainly in the Paleozoic, gave rise to the present 2400 km-long Tianshan orogenic collage that extends from the Aral Sea eastwards through Uzbekistan, Tajikistan, Kyrgyzstan, to Xinjiang in China. This paper provides an up-to-date along-strike synthesis of this orogenic collage and a new tectonic model to explain its accretionary evolution.The northern part of the orogenic collage developed by consumption of the Junggar–Balkash Ocean together with Paleozoic island arcs (Northern Ili, Issyk Kul, and Chatkal) located in the west, which may have amalgamated into a composite arc in the Paleozoic in the west and by addition of another two, roughly parallel, arcs (Dananhu and Central Tianshan) in the east. The western composite arc and the eastern Dananhu and Central Tianshan arcs formed a late Paleozoic archipelago with multiple subduction zones. The southern part of the orogenic collage developed by the consumption of the South Tianshan Ocean which gave rise to a continuous accretionary complex (Kokshaal–Kumishi), which separated the Central Tianshan in the east and other Paleozoic arcs in the west from cratons (Tarim and Karakum) to the south. Cross-border correlations of this accretionary complex indicate a general southward and oceanward accretion by northward subduction in the early Paleozoic to Permian as recorded by successive southward juxtaposition of ophiolites, slices of ophiolitic mélanges, cherts, island arcs, olistostromes, blueschists, and turbidites, which are mainly Paleozoic in age, with the youngest main phase being Late Carboniferous–Permian. The initial docking of the southerly Tarim and Karakum cratons to this complicated late Paleozoic archipelago and accretionary complexes occurred in the Late Carboniferous–Early Permian in the eastern part of the Tianshan and in the Late Permian in the western part, which might have terminated collisional deformation on this suture zone. The final stages of closure of the Junggar–Balkash Ocean resembled the small ocean basin scenario of the Mediterranean Sea in the Cenozoic. In summary, the history of the Altaids is characterized by complicated multiple accretionary and collisional tectonics.     

中国西北部造山带中几个古生代俯冲增生楔的识别与确认

中国西北部涉及古亚洲和特提斯两大构造域,造山带结构复杂,成矿地质条件优越。为推进地质找矿突破行动计划,中国地质调查局在各成矿(造山)带部署了一批1∶5万、1∶25万区域地质调查与基础地质综合研究项目,取得了一批新发现、新进展,有效提升了对各成矿带成矿地质条件的认知程度,尤其是在阿尔泰南缘、南天山、南昆仑等地识别并确认出规模可观的、成矿作用优越的板块俯冲增生楔,是造山带中的增生造山亚带,是寻找斑岩型铜、构造蚀变岩型金及多金属矿的最有利区带。“增生造山带”的构造、岩浆活动及空间展布等的确认,为地质找矿突破提供了强有力的技术支撑。     

Architecture and mineral deposit settings of the Altaid orogenic collage: a revised model

The Altaids are an orogenic collage of Neoproterozoic–Paleozoic rocks located in the center of Eurasia. This collage consists of only three oroclinally bent Neoproterozoic–Early Paleozoic magmatic arcs (Kipchak, Tuva–Mongol, and Mugodzhar–Rudny Altai), separated by sutures of their former backarc basins, which were stitched by new generations of overlapping magmatic arcs. In addition, the Altaids host accreted fragments of the Neoproterozoic to Early Paleozoic oceanic island chains and Neoproterozoic to Cenozoic plume-related magmatic rocks superimposed on the accreted fragments. All these assemblages host important, many world-class, Late Proterozoic to Early Mesozoic gold, copper–molybdenum, lead–zinc, nickel and other deposits of various types.In the Late Proterozoic, during breakup of the supercontinent Rodinia, the Kipchak and Tuva–Mongol magmatic arcs were rifted off Eastern Europe–Siberia and Laurentia to produce oceanic backarc basins. In the Late Ordovician, the Siberian craton began its clockwise rotation with respect to Eastern Europe and this coincides with the beginning of formation of the Mugodzhar–Rudny Altai arc behind the Kipchak arc. These earlier arcs produced mostly Cu–Pb–Zn VMS deposits, although some important intrusion-related orogenic Au deposits formed during arc–arc collision events in the Middle Cambrian and Late Ordovician.The clockwise rotation of Siberia continued through the Paleozoic until the Early Permian producing several episodes of oroclinal bending, strike–slip duplication and reorganization of the magmatic arcs to produce the overlapping Kazakh–Mongol and Zharma-Saur–Valerianov–Beltau-Kurama arcs that welded the extinct Kipchak and Tuva–Mongol arcs. This resulted in amalgamation of the western portion of the Altaid orogenic collage in the Late Paleozoic. Its eastern portion amalgamated only in the early Mesozoic and was overlapped by the Transbaikal magmatic arc, which developed in response to subduction of the oceanic crust of the Paleo-Pacific Ocean. Several world-class Cu–(Mo)-porphyry, Cu–Pb–Zn VMS and intrusion-related Au mineral camps, which formed in the Altaids at this stage, coincided with the episodes of plate reorganization and oroclinal bending of magmatic arcs. Major Pb–Zn and Cu sedimentary rock-hosted deposits of Kazakhstan and Central Asia formed in backarc rifts, which developed on the earlier amalgamated fragments. Major orogenic gold deposits are intrusion-related deposits, often occurring within black shale-bearing sutured backarc basins with oceanic crust.After amalgamation of the western Altaids, this part of the collage and adjacent cratons were affected by the Siberian superplume, which ascended at the Permian–Triassic transition. This plume-related magmatism produced various deposits, such as famous Ni–Cu–PGE deposits of Norilsk in the northwest of the Siberian craton.In the early Mesozoic, the eastern Altaids were oroclinally bent together with the overlapping Transbaikal magmatic arc in response to the northward migration and anti-clockwise rotation of the North China craton. The following collision of the eastern portion of the Altaid collage with the Siberian craton formed the Mongol–Okhotsk suture zone, which still links the accretionary wedges of central Mongolia and Circum-Pacific belts. In the late Mesozoic, a system of continent-scale conjugate northwest-trending and northeast-trending strike–slip faults developed in response to the southward propagation of the Siberian craton with subsequent post-mineral offset of some metallogenic belts for as much as 70–400 km, possibly in response to spreading in the Canadian basin. India–Asia collision rejuvenated some of these faults and generated a system of impact rifts.     

西天山构造演化与优势矿产成矿规律

西天山位于中亚增生型造山带的西南缘,夹于准噶尔地块和塔里木克拉通之间.西天山造山带的构造演化与天山洋的俯冲?关闭过程密切相关.西天山地质构造复杂,成矿作用独特,既可形成与活动陆缘有关的斑岩铜金矿和火山?沉积岩型铁锰矿,也可发育与伸展构造有关的海底热水沉积型铅锌矿和浅成低温热液型金矿等多个集中区.西天山地质构造演化和成矿作用一直是地质学家关注和研究的热点,近年来的地质找矿和基础研究工作也取得一系列重大进展,但同时也存在一些急待解决的问题.本文通过对区域地质背景、沉积建造、岩浆演化、成矿地质特征与物质来源、控矿因素等方面资料的综合研究,认为西天山造山带从前寒武纪到晚古生代经历了古陆边缘裂解、洋?陆俯冲增生、陆?陆碰撞及后造山伸展等地质过程;与此相应形成了多个成矿区带,主要包括:（1）哈尔达坂前寒武纪古陆边缘裂陷盆地环境的铅锌成矿带,（2）与博罗科努古生代洋?陆俯冲、碰撞?碰撞后伸展环境有关的金铜铅锌多金属成矿带,（3）与阿吾拉勒晚古生代岛弧?弧后盆地有关的铁多金属成矿带,（4）那拉提古生代岛弧金铜多金属成矿带.在此基础上建立了西天山主要成矿区带的成矿模式,厘定了与西天山沉积建造?构造活动?岩浆活动有关的成矿序列,总结了西天山铁铜铅锌金等优势矿产时空结构模型.      

新疆晚古生代大陆边缘成矿系统与成矿区带初步探讨

新疆地处中亚成矿域的中段，古生代大陆边缘增生明显、构造和岩浆活动强烈、矿产资源丰富。古生代大陆边缘成矿作用主要集中在两个时期，即以阿尔泰南缘为主的早中泥盆世和以天山为主的早石炭世。本文在综合研究及与境外对比的基础上，按照北疆地区晚古生代大陆边缘的构造动力学和成矿特征，将研究区大陆边缘成矿系统划分为：活动大陆边缘海相火山岩-盆地流体成矿系统，活动大陆边缘火山岛弧-岩浆活动成矿系统和被动大陆边缘沉积盆地-热水活动成矿系统三类。同时对形成于大陆边缘的成矿区带进行划分，主要包括：阿勒泰南缘晚古生代活动大陆边缘块状硫化物成矿带；阿尔泰南缘-东准噶尔活动大陆边缘卡拉先格尔岛弧斑岩铜金成矿带；东天山晚古生代活动大陆边缘铜钼锌成矿区带；西准噶尔洋内弧斑岩-浅成低温热液铜金成矿区带；西天山（伊犁地块）活动大陆边缘金铜成矿区带；塔里木板块被动大陆边缘沉积型铅锌成矿带。本文认为大陆增生与成矿作用的关系是矿床学和成矿系统研究的重要内容，成矿区带是成矿系统发生成矿作用的响应，而成矿系统是成矿区带形成的本质。     

有关新疆铜矿找矿勘查的几点启示

近二十年来,新疆铜矿勘查取得了显著成就,也展示了更好的未来,本文根据新疆铜矿的基本成矿规律与分布特征,提出了新疆铜矿找矿的三个主攻类型、三个远景类型及有利于形成铜矿的四片地块,铜矿趋向于集中在板块的结合部位、古生代是新疆铜矿的成矿时期,并就如何进一不开展新疆铜矿的找矿勘查提出了建议。     

中国西北地区中亚型造山—成矿作用的研究意义和进展

地处欧亚大陆核心的中亚型造山带,由多条古生代缝合带与多个前寒武纪小陆块镶嵌,基此 形成 中新生代盆地—山脉耦合的构造格局,并具有独特的构造演化史和动力学机制。中亚型造山 作用造就了丰富的矿产资源,矿床类型多样,超大型矿床汇聚,是解决我国21世纪矿产资源 问题的关键地带。但目 前尚未查明其成矿规律、成矿机制和找矿方向,因而急需研究。     

Rudny Altai base-metal belt: Localization of massive sulfide mineralization

The geodynamic evolution, deep structure, and metallogenic regionalization of the Rudny Altai are considered in terms of plate tectonics. The base-metal massive sulfide deposits are genetically related to the group of basalt-andesite-rhyolite sequences formed in rift or island-arc geodynamic setting in the Devonian at the early stage of Hercynian tectogenesis. Taking into account economic reserves of ore and major metals (Cu, Pb, Zn, Au, Ag), as well as lateral and vertical regional metallogenic zoning of the Rudny Altai, the localization of massive sulfide mineralization in ore-bearing structural elements and particular deposits has been specified. The ore productivity of ore-bearing geochronological levels for base metals and the contribution of these levels to the total reserves of the region are characterized in detail. The Rudny Altai basemetal belt is regarded as a continuous ore-bearing structural unit situated in Russia and Kazakhstan.     

土屋-延东斑岩型铜(钼)矿床多源信息找矿模型

为提高东天山铜镍成矿带内的矿产勘查效益，文章综合了区域成矿环境、矿床特征、地球物理场、地球化学场等成矿信息，尝试建立了土屋—延东斑岩型铜钼矿床的多源信息找矿模型。认为成矿带内铜矿资源远景良好，必将成为我国又一个铜矿资源潜力区。     

Tectonics,magmatism, and mineralization of Circum–Balkash–Junggar area in the Central Asian Orogenic Belt

ABSTRACT

The Circum–Balkhash–Junggar area, including mostly Kazakhstan, NW China, Russia, Kyrgyzstan, Tajikistan, Uzbekistan, and Mongolia, occupies an important tectonic position of the Central Asian Orogenic Belt (CAOB) (Figure 1). Tectonically, this vast area records the complicated geodynamic processes, among which the most prominent stages are the formation of the U-shaped Kazakhstan Orocline and its interactions with adjacent Altai (Altay), Junggar (West Junggar, Junggar Basin, and East Junggar), and Tianshan orogenic collages in the Palaeozoic, bearing large-scale mineral deposits. The formation of the Late Palaeozoic mineral deposits is related to the tectonic evolution of the Devonian and Carboniferous–Permian volcano-magmatic arcs in the region. However, the link between the metallogeny and the evolution of the volcano-magmatic arcs is not well understood and existing geodynamic models have not explained satisfactorily the mechanism of the huge metallogenic belt. Therefore, this special issue focuses on the formation of the Late Palaeozoic porphyry Cu deposits and their link to the tectonic evolution of the Devonian and Carboniferous–Permian volcano-magmatic arcs with emphasis on comparative studies across the international borders.     

The Junggar Immature Continental Crust Province and Its Mineralization

According to the study on the peripheral orogenic belts of the Junggar basin and combined with the interpretation of geophysical data, this paper points out that there is an Early Paleozoic basement of immature continental crust in the Junggar area, which is mainly composed of Neoproterozoic-Ordovician oceanic crust and weakly metamorphosed covering sedimentary rocks. The Late Paleozoic tectonism and mineralization were developed on the basement of the Early Paleozoic immature continental crust. The Junggar metallogenic province is dominated by Cr, Cu, Ni and Au mineralization. Those large and medium-scale deposits are mainly distributed along the deep faults and particularly near the ophiolitic melange zones, and formed in the Late Paleozoic with the peak of mineralization occurring in the Carboniferous-Permian post-collisional stage. The intrusions related to Cu, Ni and Au mineralization generally have low Is, and positive εNd(t) values. The δ34S values of the ore deposits are mostly near zero, and t     

End-Permian to mid-Triassic termination of the accretionary processes of the southern Altaids: implications for the geodynamic evolution,Phanerozoic continental growth,and metallogeny of Central Asia

The Altaids is one of the largest accretionary orogenic collages in the world with the highest rate of Phanerozoic continental growth and significant metallogenic importance. It is widely accepted that subduction-related orogenesis of the Altaids started in the late Precambrian and gradually migrated southward (present coordinates). However, it is uncertain when and how the building of the Altaids was finally completed. Based on structural geology, geochemical, geochronological, and paleomagnetic data, this paper presents late Paleozoic to early Mesozoic accretionary tectonics of two key areas, North Xinjiang in the west and Inner Mongolia in the east, together with neighboring Mongolia. The late Paleozoic tectonics of North Xinjiang and adjacent areas were characterized by continuous southward accretion along the wide southern active margin of Siberia and its final amalgamation with the passive margin of Tarim, which may have lasted to the end-Permian to early/mid-Triassic. In contrast, in Inner Mongolia and adjacent areas two wide accretionary wedges developed along the southern active margin of Siberia and the northern active margin of the North China craton, which may have lasted to the mid-Triassic. The final products of the long-lived accretionary processes in the southern Altaids include late Paleozoic to Permian arcs, late Paleozoic to mid-Triassic accretionary wedges composed of radiolarian cherts, pillow lavas, and ophiolitic fragments, and high-pressure/ultrahigh-pressure metamorphic rocks. Permian Alaskan-type zoned mafic-ultramafic complexes intruded along some major faults of the Tien Shan. We define a new Tarim suture zone immediately north of the Tarim craton that is probably now buried below the Tien Shan as a result of northward subduction of the Tarim block in the Cenozoic. The docking of the Tarim and North China cratons against the southern active margin of Siberia in the end-Permian to mid-Triassic resulted in the final closure of the Paleoasian Ocean and terminated the accretionary orogenesis of the southern Altaids in this part of Central Asia. This complex geodynamic evolution led to formation of giant metal deposits in Central Asia and to substantial continental growth.     

Lead isotope variations across terrane boundaries of the Tien Shan and Chinese Altay

The Altaid orogen was formed by aggregation of Paleozoic subduction–accretion complexes and Precambrian basement blocks between the Late Proterozoic and the Early Mesozoic. Because the Altaids are the site of abundant granitic plutonism and host some of the largest gold deposits in the world, understanding their formation has important implications on the comprehension of Phanerozoic crustal growth and metallogeny. In this study, we present the first extensive lead isotope data on magmatic and metasedimentary rocks as well as ore deposits of the southern part of the Altaids, including the Tien Shan (Tianshan) and southern Altay (Altai) orogenic belts. Our results show that each terrane investigated within the Tien Shan and southern Altay is characterized by a distinct Pb isotope signature and that there is a SW–NE Pb isotope gradient suggesting a progressive transition from a continental crust environment in the West (the Kyzylkum and Kokshaal segments of the Southern Tien Shan) to an almost 100% juvenile (MORB-type mantle-derived) crust environment in the East (Altay). The Pb isotope signatures of the studied ore deposits follow closely those of magmatic and metasedimentary rocks of the host terranes, thus supporting the validity of lead isotopes to discriminate terranes. Whereas this apparently suggests that no unique reservoir has been responsible for the huge gold concentration in this region, masking of a preferential Pb-poor Au-bearing reservoir by mixing with Pb-rich crustal reservoirs during the mineralizing events cannot be excluded.     

成矿系统分析与新类型矿床预测

新类型矿床的发现常能带来矿产储量的巨量增长 ,是新世纪中保障矿产资源供应的一个重要途径。成矿系统分析对发现新类型矿床有重要意义。 (1)掌握一个区域成矿系统中各矿床类型间相互关系 ,由已知矿床类型找寻未知矿床类型 ,这已在长江中下游成矿带的找矿历史中得到证实。 (2 )认识成矿系统的空间结构 ,主要是垂向分带 ,有助于找寻深部的隐伏矿床类型。 (3)查明成矿系统的时间结构 ,包括成矿过程中矿床类型的迭变关系 ,可由已知矿化链条查找缺失的矿化链条 (矿床类型 ) ,这在岩浆热液成矿系统中常能奏效。 (4 )查明成矿系统中矿床类型多样性的制约因素 ,可据此分析相关区域中发现新类型矿床的潜力。 (5)研究新的成矿环境和新的成矿作用 ,从而发现新的矿床类型。在生物成矿系统、深海成矿系统、低温成矿系统、构造成矿系统及叠加成矿系统中有更大的发现新类型矿床的几率。文中提出近期内可能发现的新的铂族元素矿床类型。笔者还指出今后的找矿目标 ,应是整个成矿系统 ,而不是局限于单个矿床及单个矿床类型 ,这样才可能不失去发现新类型矿床的机会。     

Paleozoic Tectono-Metallogeny in the Tianshan-Altay Region, Central Asia

The research on Paleozoic tectonics and endogenic metallogeny in the Tianshan-Altay region of Central Asia is an important and significant project. The Altay region, as a collision zone of the Early Paleozoic(500–397 Ma), and the Tianshan region, as a collision zone of the early period in the Late Paleozoic(Late Devonian-Early Carboniferous, 385–323 Ma), are all the result of nearly N-S trending shortening and collision(according to recent magnetic orientation). In the Late Devonian-Early Carboniferous period(385–323 Ma), regional NW trending faults displayed features of dextral strike-slip motion in the Altay and Junggar regions. In the Tianshan region, nearly EW-trending regional faults are motions of the thrusts. However, in the Late Carboniferous-Early Permian period(323–260 Ma), influenced by the long-distance effect induced from the Ural collision zone, those areas suffered weaker eastward compression, the existing NW trending faults converted into sinistral strike-slip in the Altay and Junggar regions, and the existing nearly E-W trending faults transferred into dextral strike-slip faults in the Tianshan region. The Rocks of those regions in the Late Carboniferous-Early Permian period(323–260 Ma) were moderately ruptured to a certain tension-shear, and thus formed a number of world famous giant endogenic metal ore deposits in the Tianshan-Altay region. As to the Central Asian continent, the most powerful collision period may not coincide with the most favorable endogenic metallogenic period. It should be treated to "the orogenic metallogeny hypothesis" with caution in that region.     

铜陵矿集区深部找矿工作的一些思考

铜陵矿集区深部结构特征为该区大规模成岩成矿作用奠定了良好的基础,浅表已发现的矿床只是矿集区成矿系统的一部分。除此之外,深部还应有多个可以找寻的矿床(矿体)的富集空间。与成矿相关的花岗岩研究表明,铜陵矿集区可能存在与宁芜火山盆地同期的成岩成矿作用,是铜陵矿集区找矿的新方向。铜陵矿集区奥陶系灰岩中铜金矿化作用的初步研究表明,除传统矿床类型外,前泥盆纪地层中的成矿作用应该在今后的找矿工作中得到关注。覆盖区成矿预测初步研究表明,铜陵矿集区向斜核部及褶皱倾伏端等地段具有与已知典型矿床相似的成矿条件。铜陵矿集区的进一步找矿工作应该在上述地段运用矿田构造系统分析、深部地球物理探测和工程验证等方法逐步展开。     

东天山板块构造分区、演化与成矿地质背景研究

围绕东天山找矿的基础地质构造问题，编制了新的1：50万东天山地区大地构造图和1：100万东天山地区成矿规律图。划分出新的大地构造单元，确认了中天山结晶轴的存在。将东天山地区显生宇以来的大地构造演化划分为洋壳扩张、俯冲岛弧、弧后盆地和碰撞造山期及造山期后伸展5个阶段，各阶段分别形成了对应的矿床和矿床组合，明确了主要矿床如土屋铜矿（泥盆纪－早石炭世增生弧背景）、黄山－香山铜镍矿（早二叠世同碰撞背景）的成矿时代和成矿环境。     

西天山松湖铁矿控矿因素与找矿前景分析

松湖铁矿是近年来在西天山阿吾拉勒成矿带上新发现的中型铁矿床之一。从成矿地质背景、成矿条件方面入手,确定控矿因素。在此基础上,剖析物探、化探资料,建立松湖铁矿的找矿模型,同时,将松湖铁矿与中国及国外典型IOCG矿床进行对比,进行找矿前景分析。认为赋矿地层、断裂构造、岩浆岩等为重要的控矿因素;化探资料显示,异常套合较好,各异常中心显示良好的成矿特征和地球化学背景,并且各单元素异常的展布与区域断裂构造走向几乎完全一致,具有明显的断裂控矿特征,磁异常明显,对矿区外围4个磁异常进行钻探验证,其中3个异常已发现矿化或矿层;通过对比,发现松湖铁矿与IOCG型矿床有相似之处。综合上述特征,认为松湖矿床深部及外围具有较大的找矿前景,有望成为西天山阿吾拉勒成矿带上的大型铁矿床之一。     

东天山准噶尔-哈萨克斯坦板块与塔里木板块缝合线的再厘定及其意义

摘要：文中以板块构造理论为指导思想,以大量地质、物探、化探、遥感资料为依据,在全面分析前人对东天山造山带板块缝合线的认识基础上,重新厘定研究区准噶尔-哈萨克斯坦板块与塔里木板块缝合带的位置。经研究确定：东天山造山带康古尔塔格和阿齐克库都克两条断裂之间所夹持的区域,为准噶尔-哈萨克斯坦板块和塔里木板块陆 陆碰撞的缝合带,即康古尔塔格-阿齐克库都克碰撞缝合带。该碰撞缝合带既有板块边界划分意义,又有实体物质组成和特定结构、构造及其演化历史的独立构造单元,也是东天山地区重要的多金属成矿带,故该带对东天山造山带Cu、Ni、Au、Ag等多金属矿产的形成和空间分布起着重要的控制作用。     

东天山-北山Cu- Ni- Au- Pb- Zn成矿带主要成矿地质特征及潜力分析

文章通过潜力评价成果汇总和综合分析,结合找矿新理论和该区找矿新进展,重新划定(修定)了东天山-北山Cu-Ni-Au-Pb-Zn重点成矿带的边界。东天山-北山Cu-Ni-Au-Pb-Zn重点成矿带位于西伯利亚板块和塔里木板块之间,在漫长的地质构造演化过程中经历了多次裂解、拼合、造山等构造运动,相应地发生过多期、多阶段的成矿作用,致使此带形成了众多不同矿种、不同类型的矿床,是矿产勘查突破的有利区带。作者从研究区构造演化历史出发,分析了该带区域成矿地质背景,结合带内最新的找矿进展,修订了东天山-北山Cu-Ni-Au-Pb-Zn重点成矿带的成矿谱系,深化了对本成矿带的成矿规律认识;新一轮矿产资源潜力评价证实,带内仍然具有极大的资源潜力,在此基础上,在本带划分了19个远景区,其中9个为重点远景区,10个为一般远景区;提出了带内可能发现新矿床类型(如:砂岩型铀矿、斑岩型金矿等)和新矿种(如稀有稀散金属等);建议本带下一步勘查部署的主攻矿种为Ni、Cu、Mo、Au、W,兼顾Pb、Zn、Ag、Fe和Mn;建议本带主攻类型为基性-超基性岩型镍铜矿、斑岩型铜(钼、金)矿、破碎蚀变岩型金矿、碳酸盐岩-细碎屑岩型铅锌银多金属矿、海相火山岩型铁矿、矽卡岩型银矿以及沉积型锰矿等。该项工作对指导本成矿带下一步矿产勘查部署工作有一定指导意义。