Spatial-temporal distribution and geochemistry of highly evolved Mesozoic granites in Great Xing’an Range,NE China:Discriminant criteria and geological significance

Highly evolved granite is an important sign of the mature continent crust and closely associated with deposits of rare metals.In this work,the authors undertake systematically zircon U-Pb ages and whole rock elemental data for highly evolved granitic intrusions from the Great Xing’an Range(GXR),NE China,to elucidate their discriminant criteria,spatial-temporal distribution,differentiation and geodynamic mecha-nism.Geochemical data of these highly evolved granites suggest that high w(SiO_(2))(>70%)and differentiation index(DI>88)could be quantified indicators,while strong Eu depletion,high TE_(1,3),lowΣREE and low Zr/Hf,Nb/Ta,K/Rb could only be qualitative indicators.Zircon U-Pb ages suggest that the highly evolved gran-ites in the GXR were mainly formed in Late Mesozoic,which can be divided into two major stages:Late Ju-rassic-early Early Cretaceous(162-136 Ma,peak at 138 Ma),and late Early Cretaceous(136-106 Ma,peak at 126 Ma).The highly evolved granites are mainly distributed in the central-southern GXR,and display a weakly trend of getting younger from northwest to southeast,meanwhile indicating the metallogenic potential of rare metals within the central GXR.The spatial-temporal distribution,combined with regional geological data,indicates the highly evolved Mesozoic granites in the GXR were emplaced in an extensional environ-ment,of which the Late Jurassic-early Early Cretaceous extension was related to the closure of the Mongol-Okhotsk Ocean and roll-back of the Paleo-Pacific Plate,while the late Early Cretaceous extension was mainly related to the roll-back of the Paleo-Pacific Plate.

Zircon U-Pb geochronology,geochemistry and tectonic implication of volcanic rocks from Manketouebo Formation in Keyihe area of northern Great Xing'an Range

Zircon U-Pb isotope dating and whole-rock geochemical analyses were undertaken for the rhyolite,rhyolitic lithic crystal tuff and dacitic tuff from the Manketouebo Formation in the Keyihe area,in order to constrain their genesis and tectonic significance.Zircon LA-ICP-MS U-Pb data indicate that the rhyolite and rhyolitic lithic crystal tuff were formed during 137±5 Ma and 143±1 Ma,respectively.These volcanic rocks have high SiO2(70.03%–76.46%)and K2O+Na2O(8.10%–9.52%)contents,but low CaO(0.03%–0.95%)and MgO(0.07%–0.67%)contents,which belong to the peraluminous and high-K calc-alkaline rocks.They are enriched in light rare earth elements(REEs),and exhibit fractionation of light over heavy REEs,withδEu values of 0.37–0.83.The volcanic rocks are enriched in LILEs(e.g.,Rb,U and K)and depleted in HFSEs(e.g.,Nb,Ti,P and Ta).The chemical composition suggests that these volcanic rocks formed by partial melting of crust material.Combined with previous regional research results,the authors consider that the volcanic rocks of the Manketouebo Formation in the Keyihe area were formed under an extensional environment related to the closure of the Mongolia–Okhotsk Ocean.

Origin and evolution of ore-forming fluid for the Gaosongshan gold deposit, Lesser Xing’an Range:Evidence from fluid inclusions,H-O-S-Pb isotopes

Epithermal gold deposits are typical precious metal deposits related to volcanic and subvolcanic magmatism.Due to the lack of direct geological and petrographic evidences,the origin of the ore-forming fluid is deduced from the spatial diagenesis-mineralization relationship,chronological data,physicochemical characteristics of mineral fluid inclusions,mineral or rock elements and isotopic geochemical characteristics.By objectively examining this scientific problem via a geological field survey and petrographic analysis of the Gaosongshan epithermal gold deposit,we recently discovered and verified the following points:(1) Pyrite-bearing spherical quartz aggregates (PSQA) occur in the rhyolitic porphyry;(2) the mineralization is structurally dominated by WNW- and ENE-trending systems and occurs mostly in hydrothermal breccias and pyrite-quartz veins,and the ore types are mainly hematite-crusted quartz,hydrothermal breccia,massive pyrite-quartz,etc.;(3) the alteration types consist of prevalent silicification,sericitization,propylitization and carbonation,with local adularization and illitization.The ore minerals are mainly pyrite,primary hematite,native gold,and electrum,with lesser amounts of chalcopyrite,magnetite,sphalerite,and galena,indicating a characteristic epithermal low-sulfidation deposit.The ore-forming fluid may have been primarily derived from magmatic fluid exsolved from a crystallizing rhyolitic porphyry magma.Further zircon U-Pb geochronology,fluid inclusion,physicochemical and isotopic geochemical analyses revealed that (1) rhyolitic porphyry magmatism occurred at 104.6 ± 1.0 Ma,whereas the crystallization of the PSQA occurred at 100.8 ± 2.1 Ma;(2) the hydrothermal fluid of the pre-ore stage was an exsolved CO2-bearing H2O-NaCl magmatic fluid that produced inclusions mainly composed of pure vapor (PV),vapor-rich (WV) and liquid-rich (WL) inclusions with a small number of melt-(M) and solid-bearing (S) inclusions;mineralization-stage quartz contains WL and rare PV,WV and pure liquid (PL) inclusions characterized by the H2O-NaCl system with low formation temperatures and low salinities;(3) the characteristics of hydrogen,oxygen,sulfur,and lead isotopes and those of rare earth elements (REEs) provide insight into the affinity between PSQA and orebodies resulting from juvenile crust or enriched mantle.Combined with previous research on the mineralogenetic epoch (99.32 ± 0.01 Ma),we further confirm that the mineralization of the deposit occurred in the late Early Cretaceous,which coincides with the extension of the continental margin induced by subduction of the Pacific Plate beneath the Eurasian Plate.The formation of the ore deposit was proceeded by a series of magmatic and hydrothermal events,including melting of enriched juvenile crust,upwelling,the eruption and emplacement of the rhyolitic magma,the exsolution and accumulation of magmatic hydrothermal fluid,decompression,the cooling and immiscibility/boiling of the fluid,and mixing of the magmatic fluid with meteoric water,in association with water-rock interaction.

Geochemical Characteristics and Geological Significance of Early Permian Baya'ertuhushuo Gabbro in South Great Xing'an Range

Field geological investigation and geochemical analysis are carried out on Baya＇ertuhushuo Gabbro in South Great Xing＇an Range. Field investigation reveals that the gabbro is a magmatic intrusion rather than a component of an ophiolite suite as previously thought. Zircon laser ablation inductively coupled plasma mass spectroscopy （LA-ICP-MS） U-Pb dating indicates the gabbro was formed in 274-275 Ma, just as the widespread volcanic rocks of Dashizhai Formation （P1d）, monzogranites and miarolitic alkali-feldspar granites in the study area. The gabbro has SiO2 content between 47.23 wt% and 50.17 wt%, high MgO and FeOT contents of 6.95-11.29 wt% and 7.32- 12.24wt%, respectively, and it belongs to low-K tholeiitic series in the SiO2-K2O diagram. The Chondrite-normalized rare earth element （REE） patterns and primitive mantle-normalized spider diagrams of the gabbro are similar to those of Normal Mid-Ocean Ridge Basalt （N-MORB） except for the enrichment of large ion lithophfle elements （LILE）, such as Rb, Ba and K. In trace element tectonic discriminative diagrams, the samples are mainly plotted in the N-MORB field, and Zircon in situ Lu-Hf isotopic analysis also indicates the gabbro originated from depleted mantle. Through synthetic studies of the geochemical characteristics and petrogenesis of Baya＇ertuhushuo gabbro, volcanic rocks of Dashizhai Formation and granitoids in the area, it is suggested that the early Permian magmatism in the Xilinhot-Xiwuqi area formed in the tectonic setting of asthenosphere upwelling, which was caused by breaking-off of the subducted Paleo-Asian Ocean slab.

Early Cretaceous Adakitic Rocks in the Northern Great Xing’an Range, NE China: Implications for the Final Closure of Mongol-Okhotsk Ocean and Regional Extensional Setting

A large amount of igneous rocks in NE China formed in an extensional setting during Late Mesozoic. However, there is still controversy about how the Mongol-Okhotsk Ocean and the Paleo-Pacific Ocean effected the lithosphere in NE China. In this paper, we carried out a comprehensive study for andesites from the Keyihe area using LA-ICP-MS zircon UPb dating and geochemical and Hf isotopic analysis to investigate the petrogenesis and tectonic setting of these andesites. The U-Pb dating yields an Early Cretaceous crystallization age of 128.3±0.4 Ma. Geochemically, the andesites contain high Sr(686-930 ppm) and HREE contents, low Y(11.9-19.8 ppm) and Yb(1.08-1.52 ppm) contents, and they therefore have high Sr/Y(42-63) and La/Yb(24-36) ratios, showing the characteristics of adakitic rocks. Moreover, they exhibit high K2O/Na2O ratios(0.57-0.81), low Mg O contents(0.77-3.06 wt%), low Mg# value(17-49) and negative εHf(t) values(-1.7 to-8.5) with no negative Eu anomalies, indicating that they are not related to the oceanic plate subduction. Based on the geochemical and isotopic data provided in this paper and regional geological data, it can be concluded that the Keyihe adakitic rocks were affected by the Mongol-Okhotsk tectonic regime, forming in a transition setting from crustal thickening to regional extension thinning. They were derived from the partial melting of the thickened lower crust. The closure of the Mongol-Okhotsk Ocean may finish in early Early Cretaceous, followed by the collisional orogenic process. The southern part region of its suture belt was in a post-orogenic extensional setting in the late Early Cretaceous.

Recognition of Early Paleozoic Magmatisms in the Supposed Proterozoic Basements of Zhalantun, Great Xing’an Range, NE China

The Zhalantun terrane from the Xing’an massif, northeast China, was used to be considered as Proterozoic basements. However, amounts of detrital zircon ages from the meta-sedimentary rocks deny the existence of Precambrian basements recently. Notably, magmatic rocks were barely reported to limit the exact ages of the Zhalantun basements. In this study, we collected rhyolite, gabbro and quartz diorite for zircon in-situ U-Pb isotopic dating, which yield crystallization ages of ~505 Ma, ~447 Ma and ~125 Ma, respectively. Muscovite schist and siltstone define maximum depositional ages of ~499 Ma and ~489 Ma, respectively. Additionally, these dated supracrustal rocks and plutons also yield ancient detrital/xenocryst zircon ages of ~600-1000 Ma, ~1600-2220 Ma, ~2400 Ma, ~2600-2860 Ma. Based on the whole-rock major and trace element compositions, the ~505 Ma rhyolites display high SiO2 and alkaline contents, low Fe2O3T, TiO2 and Al2O3, and relatively high Mg O and Mg#, which exhibit calc-alkaline characteristics. These rhyolites yield fractionated REE patterns and negative Nb, Ta, Ti, Sr, P and Eu anomalies and positive Zr anomalies. The geochemistry, petrology and Lu-Hf isotopes imply that rhyolites were derived from the partial melting of continental basalt induced by upwelling of sub-arc mantle magmas, and then experienced fractional crystallization of plagioclase, which points to a continental arc regime. The ~447 Ma gabbros exhibit low Si O2 and alkaline contents, high Fe2 O3 T, Ti O2, Mg O and Mg#. They show minor depletions of La and Ce, flat MREE and HREE patterns, and negative Nb, Ta, Zr and Hf anomalies. Both sub-arc mantle and N-MORB-like mantle were involved in the formation of the gabbros, indicative of a probable back-arc basin tectonic setting. Given that, the previously believed Proterozoic supracrustal rocks and several plutons from the Zhalantun Precambrian basements were proved to be Paleozoic to Mesozoic rocks, among which these Paleozoic magmatic rocks were generally related to subduction regime. So far, none Proterozoic rocks have been identified from the Zhalantun Precambrian basement, though some ~600-3210 Ma ancient detrital/xenocryst zircons were reported. Combined with ancient zircon ages and newly reported ~2.5 Ga and ~1.8 Ga granites from the south of the Zhalantun, therefore, the Precambrian rocks probably once exposed in the Zhalantun while they were re-worked and consumed during later long tectonic evolutionary history, resulting in absence of Precambrian rocks in the Zhalantun.

Felsic Igneous Rocks in the Hua'aobaote Pb-Zn-Ag Polymetallic Orefield,Southern Great Xing'an Range:Genesis,Metallogenetic and Tectonic Significance

The Hua’aobaote Pb-Zn-Ag Polymetallic orefield is situated in the southern section of the Great Xing’an Range(GXAR),which has experienced extensive magmatism.Since the Paleozoic,there are two stages of magmatism in Hua’aobaote orefield occurred in the Paleozoic and Mesozoic.The Mesozoic magmatism is of great significance for the PbZn-Ag Polymetallic mineralization in Hua’aobaote orefield.In this study,new geochemical data was obtained to discuss the timing and petrogenesis of the magmatic rocks and its geodynamic and metallogenic significance.Zircon U-Pb ages reveal that the felsic igneous rocks from the Hua’aobaote orefield were formed in the Early Permian(294.8±3.2 Ma)and Early Cretaceous(132.6±1.4 Ma).Geochemically,the Early Permian granodiorite porphyrite is characterized by high Sr/Y(42-63)ratios and Mg^(#)(62.24-70.74)values and low heavy rare earth element(HREE)(5.09-6.79 ppm)contents.The granodiorite porphyrite is also characterized by depleted Sr-Nd initial isotopic signatures[ε_(Nd)(t)=5.91-7.59,(^(87)Sr/^(86)Sr)i=0.7029-0.7030],exhibiting adakitic characteristics.The Early Cretaceous granite porphyry and rhyolite are A-type felsic igneous rocks,and demonstrate high SiO_(2),Na_(2)O+K_(2)O and rare earth element(REE)contents,low CaO and MgO contents,low(^(87)Sr/^(86)Sr)i ratios(0.7044-0.7058),and positive ε_(Nd)(t)values(2.57-4.65).Whole-rock Pb isotopic compositions in granodiorite porphyrite are:206Pb/204Pb=17.631-18.149,^(207)Pb/^(204)Pb=15.422-15.450,and ^(208)Pb/^(204)Pb=37.325-37.729.The granite porphyry and rhyolite have initial ^(206)Pb/^(204)Pb,^(207)Pb/^(204)Pb,and ^(208)Pb/^(204)Pb ratios of 18.106-19.309,15.489-15.539,and 37.821-38.05,respectively.Sr-Nd-Pb isotopic evidence suggests that the Early Permian granodiorite porphyrite is likely to derive from slab melts and modified by peridotitic mantle wedge in the subduction tectonic setting of the Paleo-Asian Ocean.The Early Cretaceous A-type felsic igneous rocks were derived from juvenile lower crust,accompanied by limited crustal contamination and various degree of fractional crystallisation during magma emplacement.The Early Cretaceous magmatism and related mineralization were formed in a post-orogenic tectonic setting that attributed to the closure of the Mongol-Okhotsk Ocean.Pb isotopic data for the various rock units in the study area indicate that the Mesozoic magma source contributed substantial Pb,Zn,and Ag to the Hua’aobaote deposit.

Magmatic Evolution and Mineralization Process of the Super-Large Shihuiyao Rb–Nb–Ta Deposit,Southern Great Xing'an Range,China

Rare metal ore reserves are an important strategic resource, and their metallogenic mechanism and mineralization studies have also been received widespread international attention.

The Cu-Mo Mineralization of the Late Jurassic Porphyry in the Northern Great Xing'an Range: Constraints from Zircon U-Pb Ages of the Ore-Causative Granites

The Great Xing’an Range(GXAR)is one of the most important metallogenic belts in China.Previous study has shown that porphyry Cu-Mo deposit distributed in the northern Great Xing’an Range formed mainly in two stages:(1)Early Ordovician,such as Duobaoshan and Tongshan deposits(Liu et al.,2017);2)Triassic-Early Jurassic,including Wunugetushan,Taipingchuan and Badaguan deposits(Tang et al.,2016).In recent years,two potential porphyry Cu-Mo deposits,Huoluotai and Xiaokele,were discovered in the Erguna Block,northern GXAR(Figs.1a–b).However,the ore formation ages and regional metallogenic regularity are ambiguous due to the lack of isotopic ages.Two zircon U-Pb ages from the ore-causative granites were reported in this paper,with the aims to constrain the metallogenic ages and provide evidence for study of the regional metallogenic regularity and ore prospect prediction.

New Discovery of the Late Triassic Terrigenous Sediments in the Great Xing＇＇an Range Region,NE China and its Geological Significance

Objective The Great Xing＇an Range is located in the eastern section of Central Asian Orogenic Belt（CAOB）.As a superposed position of multiple tectonic domains,its structural evoIlution has always been a focused issue of geological research.

METAMORPHISM IN THE LESSER HIMALAYAN CRYSTALLINES AND MAIN CENTRAL THRUST ZONE IN THE ARUN VALLEY AND AMA DRIME RANGE (EASTERN HIMALAYA)

The Arun mega\|antiform, a large N—S structure transversal to the tectonic trend of the E Nepal Himalaya, is a tectonic window offering a complete section of the Himalayan nappe pile, from the Lesser Himalayan zone to the Tethyan Himalaya. At the northern end of the Arun tectonic window (ATW), the Ama Drime—Nyonno Ri range of south Tibet exposes a section of that portion of the Main Central Thrust (MCT) zone and Lesser Himalayan Crystallines (LHC) which elsewhere in Nepal is concealed below the overlying Higher Himalayan Crystalline (HHC) nappe (Fig. 1). As throughout the Himalaya at the structural level of the MCT, the ATW is characterized by an inverted metamorphic field gradient characterized by a progression from chlorite to sillimanite grade from low to high structural levels of the nappe pile. Metamorphic peak temperatures rise from circa 400℃ in the pelitic and psammitic Precambrian metasediments of the Lesser Himalayan Tumlingtar Unit, to 550～620℃ in the overlying LHC, to over 700℃ in the muscovite\|free Barun Gneiss, the lowermost HHC unit in the Arun valley.

大兴安岭南段北大山岩体的年代学和地球化学:对岩石成因及成矿潜力的指示

大兴安岭南段发育包括维拉斯托、黄岗、安乐、大井、毛登和边家大院等锡多金属矿床,是我国北方最重要的锡多金属成矿带。北大山岩体是该锡多金属成矿带规模最大,出露最完全的花岗质侵入体,其北部主要为石英二长斑岩,南部为黑云母花岗岩,且南部岩相中常见电气石和绿柱石,被认为是区内锡多金属矿床的成矿母岩。然而,目前对该岩体岩石成因及其稀有金属成矿潜力的认识却存在较大争议。本文在对北大山岩体开展岩相学观察和锆石U-Pb定年的基础上,通过全岩地球化学和锆石Hf同位素分析,结合MELTS热力学模拟计算,试图阐明该岩体的成因类型、源区特征和演化过程,并讨论其成矿潜力。锆石U-Pb定年结果显示,北大山岩体北部的石英二长斑岩形成于143.4±1.3Ma,南部黑云母花岗岩形成于142.6±1.3Ma,与大兴安岭南段早白垩世锡多金属成矿年龄峰值相一致。北大山岩体中含自形富水矿物角闪石及黑云母、富碱(K_(2)O+Na_(2)O=8.58%~9.34%)、ACNK/CNK值介于0.97~1.02,P_(2)O_(5)含量低(<0.14%)且与SiO_(2)含量呈负相关,指示该岩体为高钾钙碱性I型花岗岩。岩体的锆石Hf同位素组成较为亏损(ε_(Hf)(t)值平均6.81,n=20),且全岩锆饱和温度较高(平均值为813℃),指示其为新生地壳物质高温熔融的产物。主量元素变化关系和MELTS模拟结果表明,北大山岩体为高钾钙碱性岩浆体系不同程度分离结晶的产物,其中北部石英二长斑岩样品之间结晶分异程度较低,而南部黑云母花岗岩的结晶分异程度较高。北大山岩体的形成时代、源区特征和氧化还原条件(△FMQ-2.5)与大兴安岭南段稀有金属花岗岩类似,具有一定的锡多金属成矿潜力,但其初融温度、挥发分组成(相对富B贫F)、分异演化程度(结晶分异和熔体-流体相互作用程度相对较低)明显不同于维拉斯托矿床成矿碱长花岗斑岩,不会是该矿床的成矿母岩。

大兴安岭北段霍洛台地区辉绿玢岩的锆石U-Pb年龄、岩石成因和构造背景

对于大兴安岭北段中生代火成岩的研究,在中酸性花岗岩和火山岩等方面已有诸多成果,相比之下,对于该区中生代基性岩浆岩具体的形成时代和岩石成因仍不明确。而且,大兴安岭北段晚侏罗世-早白垩世的构造背景也存在争议。为此,本文对大兴安岭北段霍洛台地区辉绿玢岩进行了锆石U-Pb年代学和岩石地球化学特征研究,以达到进一步明确大兴安岭北段晚中生代基性岩浆岩的形成时代、岩石成因及其构造背景的目的。结果表明:霍洛台地区辉绿玢岩锆石的加权平均年龄为(129.1±1.3) Ma,属于早白垩世;辉绿玢岩稀土元素配分曲线为平坦型,Eu异常不明显;富集大离子亲石元素(如Ba、Sr),亏损高场强元素(如Th、Ce、Ti)。霍洛台辉绿玢岩可能起源于俯冲流体交代的岩石圈地幔源区,其形成可能受到了古太平洋板块俯冲作用的影响。

小兴安岭东南部伊东林场金矿床成因探讨:来自流体包裹体和H-O-S-Pb同位素的证据

伊东林场金矿是近年来在小兴安岭-张广才岭多金属成矿带内新发现的金矿,由于研究程度较低,尚未开展系统的矿床学研究。为限定伊东林场金矿成矿物质及流体来源、矿床成因类型等关键问题,本文开展了详细的野外地质调查、岩相学和矿相学观察、流体包裹体及H-O-S-Pb同位素等分析。伊东林场金矿矿石矿物主要包括黄铁矿、黄铜矿、闪锌矿、辉银矿、方铅矿等。围岩蚀变类型主要包括硅化、黄铁矿化、绢云母化、碳酸盐化,黏土化,绿泥石化和冰长石化,其中硅化和碳酸盐化与金矿化关系最为密切。成矿过程可划分为石英-方解石-少量黄铁矿阶段(Ⅰ)、石英-方解石-多金属硫化物阶段(Ⅱ)和少量硫化物-碳酸盐阶段(Ⅲ)。流体包裹体以气液两相为主,从成矿早期到晚期各阶段平均成矿温度为311℃→260℃→200℃,逐渐降低;盐度为0.2%~4.5%NaCl_(eq),密度为0.56~0.93 g/cm^(3),为中低温、低盐度、低密度的H_(2)O-NaCl体系,成矿深度小于1 km,形成于浅成环境。H-O同位素组成显示,成矿流体主要为岩浆水与大气降水混合,以大气降水为主,并与围岩发生了明显的水-岩反应;S-Pb同位素组成表明成矿物质主要来源于赋矿火山-次火山岩。通过与区内典型的中生代低硫化型浅成低温热液型金矿床特征进行对比,结合矿床地质特征、成矿流体以及稳定同位素特征,认为伊东林场金矿床为典型的低硫化型浅成低温热液型金矿床。

开库康-依西肯地区原生晕地球化学特征及找矿意义

为指导水系沉积物测量等化探异常的解释评价,分析成矿元素地球化学特征,评价主要地质单元含矿性,在开展1∶5万水系沉积物测量的同时系统采集了研究区内各地质单元原生晕样品,并对成矿元素进行了地球化学参数统计与对比研究。原生晕地球化学特征表明:区内以中低温热液成矿作用为主,找寻Au矿化或矿床希望较大,As、Sb等元素可作为指示元素;主要地质单元含矿性评价结果显示,研究区内上侏罗统二十二站组、下白垩统龙江组为区内成矿有利部位,主成矿元素为Au,Ag为伴生元素;水系与岩石样品对比分析表明,As、Sb、Mn、Mo 4种元素表现明显次生富集,Zn、Cu、Ti 3种元素明显贫化,在水系异常圈定时应适当提高、降低异常下限。

Emplacement age of the post-orogenic A-type granites in Northwestern Lesser Xing'an Ranges, and its relationship to the eastward extension of Suo-lushan-Hegenshan-Zhalaite collisional suture zone

A great amount of alkali-feldspar and alkaline granites have been found around Nenjiang, Northwest Lesser Xing’an Ranges, but their forming ages have been a controversial subject due to the lack of reliable geological and isotopic geochronological evidence. The zircon U-Pb isotopic dating results conducted in this note indicate that these granites emplaced at 260-290 Ma, coeval with the late stage of Late Paleozoic. Studies of mineralogy, petrology andgeochemistry show that they are post-orogenic A-type granites, and consist of the northeastern extension of huge belt of Late Paleozoic A-type granite along North Xinjiang-Southeast Mongolia-Central Inner Mongolia. Therefore, we can determine that the Suolunshan-Hegenshan-Zhalaite collisional suture zone extends northeastward to Heihe with the collision age of Carboniferous.

Age,Association and Provenance of the “Neoproterozoic” Fengshuigouhe Group in the Northwestern Lesser Xing'an Range,NE China:Constraints from Zircon U-Pb Geochronology

The formation time of the Fengshuigouhe Group in the northwestern Lesser Xing＇an Range , NE China, remains controversial owing to the lake of the precise dating data. This article reports zircon U-Pb ages for the leptynite and gneissic granitoids from the Fengshuigouhe Group in the northwestern Lesser Xing＇an Range. The aim is to constrain the formation time and prove- nance of Fengshuigouhe Group. Field observation indicates that the Fengshuigouhe Group consists of a suit of metamorphic rocks （leptynite） and gneissic granitoids intruding the leptynite, and that both of them are cut by late granitic pegmatite. Zircons from two leptynites are euhedral-subhedral in shape and display oscillatory zoning in CL （cathodeluminescence） images. These detrital zircons give weighted mean ages of 255, 291,321,361, 469, and 520 Ma. The youngest age of them is interpreted to maximum deposi- tional age of the protoliths of these leptynites. Zircons from gneissic granites are euhedral and subhedral in shape and exhibit typical oscillatory zoning in CL images. The dating results indicate that the gneissic granites were formed in the Early Jurassic （185~2 Ma）. Zircons from the late granitic pegmatite are sub- hedral in shape and exhibit two types in CL images： structureless and oscillatory zoning. The former gives a weighted mean age of 143~1 Ma, considered to represent the timing of crystallization of the pegmatite, the latter yield several groups of ages： 178, 273, 319, 482, 611, and 788 Ma, representing the crystallization age of inherited or captured zircons entrained by the pegmatite. Taken together, we conclude that the Fengshuigouhe Group in the northwestern Lesser Xing＇an Range formed between Late Paleozoic （255Ma） to Early Mesozoic （185 Ma）, rather than Neoproterozoic as previously believed, and that the sediments in the Fengshuigouhe Group were sourced directly from geological bodies in the study area and adjacent regions. KEY WORDS： the Lesser Xing＇an Range, Fengshuigouhe Group, formation time, leptynite, zircon U-Pb geochronology.

Zircon SHRIMP geochronology of the Xinkailing-Kele complex in the northwestern Lesser Xing'an Range, and its geological implications

Located in the eastern portion of the Xing'an-Mongolian Orogenic Belt (XMOB), the Xinkailing-Kele complex has previously been considered to be Precambrian metamorphic rocks, mainly according to its relatively high metamorphic grade. Our filed observation, however, revealed that the complex is composed mainly of metamorphic rocks (Kele complex), tectono-schists (“Xinkailing Group”),and granitoids (Xinkailing granitic complex). Dating on these rocks using advanced SHRIMP zircon U-Pb technique indicates that: (1) Biotite-plagioclase gneiss from the Kele complex has a protolith age of 337±7Ma (2σ) and a metamorphic age of 216±3Ma (2σ); (2) the tectono-schist of the “Xinkailing Group” gave a magmatic age of 292±6Ma (2σ), indicative of felsic volcanic protolith of the schist formed in Late Paleozoic time; and (3) the Menluhedingzi and Lengchuan granites of the Xinkailing granitic complex were emplaced at167±4 (20σ) and 164±4Ma (2σ), respectively. These results suggest that the Xinkailing-Kele complex is not Precambrian metamorphic rocks and the so-called Precambrian “Nenji-ang Block” does essentially not exist. In combination with regional geological data, we propose that the Kele metamorphic complex is likely related to a collisional tectonism that took place in Triassic lime, as indicted by its metamorphic age of 216±3Ma. The Xinkailing granitic complex was emplaced along the collisional zone during Mid-Jurassic time，likely in a post-orogenic or anorogenic setting.

小兴安岭构造带早侏罗世两期俯冲事件:镁铁质侵入岩的锆石年代学、元素地球化学及Sr-Nd-Li同位素制约

位于小兴安岭构造带北缘的二龙山橄榄辉长岩及星火角闪辉长岩,锆石LA-ICP-MS定年结果分别为201±1Ma和186±1Ma。两者的矿物组成不同,星火角闪辉长岩角闪石含量较高(可达15%)。主微量元素组成显示在岩浆演化过程中二龙山橄榄辉长岩经历了橄榄石和单斜辉石的分离结晶,而星火角闪辉长岩主要经历了橄榄石的分离结晶,此外,两者显著的Sr正异常及一定程度的Eu正异常(1.07~1.38),表明两者在岩浆演化过程中都存在明显的斜长石堆晶作用。原始岩浆计算表明两者都具有弧形微量元素组成,富集大离子亲石元素和轻稀土元素,而亏损高场强元素(Nb和Ta),二龙山橄榄辉长岩属于钙碱性到高钾钙碱性岩浆岩,而星火角闪辉长岩属于钾玄岩系列。两者地幔源区都经历了俯冲沉积物熔流体交代作用的影响。此外,两者具有较为一致的Li同位素组成,同MORB以及岛弧玄武岩的锂同位素组成较为一致,或者略低于MORB,进一步限定俯冲交代物质来源为陆源沉积物。两者具有明显不同的Sr-Nd同位素组成,表明小兴安岭构造带北缘东西侧具有明显的地幔不均一性。位于小兴安岭构造带北缘西侧的186Ma星火角闪辉长岩,同古太平洋板块俯冲后撤导致的弧后伸展拉张有关;而小兴安岭构造带北缘东侧的201Ma二龙山橄榄辉长岩,与位于南部张广才岭构造带东缘的209~202Ma镁铁质岩浆岩带同期,共同揭示牡丹江洋俯冲事件发生的时限为209~201Ma,整体而言牡丹江洋俯冲事件开始的时间南部略早于北部。

大兴安岭南段小孤山锡锌矿床锡石U-Pb年龄、流体包裹体和H-O-S-Pb同位素特征

毛登-小孤山地区是大兴安岭南段锡多金属成矿带代表性矿区,由小孤山锡锌矿床和毛登锡钼铋多金属矿床组成。小孤山矿床锡石U-Pb Tera-Wasserburg谐和年龄为134.8±1.9Ma,表明其形成于早白垩世。该矿床成矿过程可划分为4个阶段:锡石-黄铁矿-石英-电气石阶段(Ⅰ阶段)、锡石-黄铜矿-闪锌矿-石英-萤石阶段(Ⅱ阶段)、闪锌矿-方铅矿-石英-萤石阶段(Ⅲ阶段)、黄铁矿-石英-方解石阶段(Ⅳ阶段)。小孤山矿床主要发育富液两相包裹体(WL型)、富气两相包裹体(WG型)及含子矿物包裹体(S型)。Ⅰ、Ⅱ和Ⅲ阶段均发育WL、WG和S型包裹体,Ⅳ阶段仅出现WL型包裹体。从Ⅰ至Ⅳ阶段流体包裹体均一温度/盐度分别为420-443℃/8.3%-52.0%NaCleqv、286-379℃/4.0%-40.2%NaCleqv、214-299℃/3.8%-36.1%NaCleqv、178-195℃/2.1%-3.3%NaCleqv,表明从早阶段到晚阶段成矿流体由高温高盐度向低温低盐度转化,且前三个阶段流体盐度波动大,暗示成矿流体发生了多次沸腾。矿床的δ18O水介于-2.6‰-11.0‰,δD介于-107‰--91‰,Ⅰ和Ⅱ阶段的成矿流体以岩浆水为主,Ⅲ阶段开始有大气降水的加入。硫化物的δ34SCDT值介于-3.3‰--0.6‰,206Pb/204Pb介于17.772-18.427,207Pb/204Pb介于15.482-15.679,208Pb/204Pb介于37.668-38.622,表明成矿物质来源于早白垩世花岗质岩浆。流体沸腾和降温是矿质沉淀的两种主要机制。