北天山中段时变重力场离散小波多尺度分解     

陈丽  艾力夏提·玉山  朱治国  李瑞 《中国地震》2020,36(4):935-944

利用北天山地区2016～2019年观测的4期流动重力观测资料，分析研究一年尺度的重力场动态变化特征，并利用小波分析方法，将不同场源深度的重力异常进行分离。通过功率谱分析，获取各阶小波重力细节对应的场源深度。研究结果表明，2017年8月9日精河M_S6.6地震前，震中位于负值集中区，四阶小波重力细节显示震中附近出现明显的四象限分布；2020年1月16日库车M_S5.6地震前，震中位于负值区，小波重力细节整体量值较小；功率谱估算的场源近似深度与2次地震的震源深度相近。  相似文献   

东天山觉罗塔格带东段早志留世中酸性侵入岩的年代学、地球化学及构造意义     

于介禄  于介江  杨万志  张元厚  郭秀玮 《吉林大学学报(地球科学版)》2019,49(3):690-708

为了确定东天山觉罗塔格带东段玉海地区中酸性侵入岩的形成时代、源区性质及其构造属性，本文对该区中酸性侵入岩进行了系统的LA-ICP-MS锆石U-Pb定年、全岩地球化学以及Sr-Nd同位素分析。2个样品中的锆石在CL图像上具明显振荡环带，Th/U值为0.28~0.59，指示其岩浆成因。对岩浆锆石定年结果表明，它们主要形成于早志留世（433.2~431.2 Ma），代表了寄主岩石的形成时代。样品w（SiO₂）=57.88%~69.01%，w（Na₂O）=3.46%~5.07%，w（K₂O）=0.50%~1.65%，Na₂O/K₂O=4.26~6.79，Mg^#=45.1~52.3，A/CNK=0.89~1.00；稀土配分模式呈右倾型，LREE/HREE=5.55~11.47，（La/Yb）_N=4.18~13.54，δEu=0.82~1.25；在微量元素蛛网图上表现为大离子亲石元素（Ba、U、K、Sr等）相对富集和高场强元素（Th、Ti、Nb、Ta）相对亏损；全岩ε_Nd（t）值介于6.1~7.0之间。研究表明，早志留世中酸性侵入岩的岩浆源区主要为年轻地壳物质，结合火成岩的组合特征、岩浆作用性质以及区域构造演化历史，认为早志留世中酸性侵入岩形成于康古尔洋板片向北（吐-哈地块）俯冲的活动大陆边缘环境，从而将康古尔大洋板片北向俯冲的时限追溯至早志留世。  相似文献   

新疆西天山卡特巴阿苏金矿床锆石U-Pb年龄、地球化学特征及其地质意义     

蔡宏明  刘桂萍  尼加提&#;阿布都逊  杨维忠  邢令 《地质通报》2019,38(5):790-801

卡特巴阿苏大型金矿床位于新疆西天山中部那拉提北缘断裂带南侧,找矿前景较好。为查明矿区容矿岩浆岩的成因及其与矿床形成的联系,对主要矿石类型含金蚀变二长花岗岩和含金石英硫化物脉进行LA-MC-ICP-MS锆石U-Pb测年和地球化学研究。结果表明,锆石稀土元素显示较陡的左倾配分模式,具有明显的正Ce异常和负Eu异常,指示岩浆锆石成因。根据锆石Ce异常值,获得含矿岩石有关岩浆岩氧逸度对数值(Log(fo_2))为-29.2～5.1,指示岩浆具有较高的氧逸度,有利于金在岩体中初步富集。同时,氧逸度具有较大的变化范围,指示岩浆演化过程中,存在明显的上地壳混染。应用锆石Ti温度计,获得含金蚀变二长花岗岩锆石结晶温度为765～975℃,反映岩浆来自下地壳缺水条件下的部分熔融。含金石英硫化物脉锆石具有较低的结晶温度(641～823℃),可能与早期角闪石的分异结晶有关。以上2种矿石类型的锆石U-Pb年龄分别为350.4±1.6Ma和348.9±1.4Ma,代表了容矿二长花岗岩的结晶年龄。岩体结晶年龄早于前人报道的矿床成矿年龄,表明岩体侵位与成矿作用无直接关系。  相似文献   

新疆图拉尔根镁铁-超镁铁质杂岩体镍铜钴成矿岩浆作用过程:流体化学与碳同位素组成制约     

张铭杰  班舒悦  李思奥  宋哲  仇哲  李立武  惠卫东  李中平 《岩石学报》2020,36(12):3673-3682

东天山造山带的图拉尔根镁铁-超镁铁杂岩体为一个早古生代长期活动的幔源岩浆通道，大型铜镍钴硫化物矿体赋存于Ⅰ号超镁铁质岩体的顶部，不同类型岩石中辉石矿物的流体挥发份化学组成以H₂O为主（平均91%，5400.4mm³/g），其次为H₂（2.0%）、H₂S（2.3%）和CO₂（2.1%）；赋矿角闪橄榄岩中CO₂和H₂S含量最高，辉长岩中流体挥发份含量低于辉石橄榄岩和橄榄辉石岩等岩浆早期结晶的岩石。CO₂和CH₄的δ¹³C值位于地壳与甲烷氧化的范围内，甲烷同系物的碳同位素组成具有正序分布模式，部分样品（TLG512）释出的CH₄和C₂H₆具有较重的δ¹³C值和反序分布特征。表明I号岩体不同类型岩石可能是不同期次岩浆活动的产物，成矿岩浆具有富H₂O和H₂S的特征，可能起源于被流体交代的亏损地幔源区，混染壳源组分可能为俯冲板片来源蚀变沉积有机质组分。  相似文献   

Redox evolution of western Tianshan subduction zone and its effect on deep carbon cycle     

《地学前缘(英文版)》2020,11(3):915-924

Knowing the phase relations of carbon-bearing phases at high-pressure(HP) and high-temperature(HT) condition is essential for understanding the deep carbon cycle in the subduction zones.In particular,the phase relation of carbon-bearing phases is also strongly influenced by redox condition of subduction zones,which is poorly explored.Here we summarized the phase relations of carbon-bearing phases(calcite,aragonite,dolomite,magnesite,graphite,hydrocarbon) in HP metamorphic rocks(marble,metapelite,eclogite) from the Western Tianshan subduction zone and high-pressure experiments.During prograde progress of subduction,carbonates in altered oceanic crust change from Ca-carbonate(calcite) to Ca,Mg-carbonate(dolomite),then finally to Mgcarbonate(magnesite) via Mg-Ca cation exchange reaction between silicate and carbonate,while calcite in sedimentary calcareous ooze on oceanic crust directly transfers to high-pressure aragonite in marble or amorphous CaCO3 in subduction zones.Redox evolution also plays a significant effect on the carbon speciation in the Western Tianshan subduction zone.The prograde oxygen fugacity of the Western Tianshan subduction zone was constrained by mineral assemblage of garnet-omphacite from FMQ-1.9 to FMQ-2.5 at its metamorphic peak(maximum P-T) conditions.In comparison with redox conditions of other subduction zones,Western Tianshan has the lowest oxygen fugacity.Graphite and light hydrocarbon inclusions were ubiqutously identified in Western Tianshan HP metamorphic rocks and speculated to be formed from reduction of Fe-carbonate at low redox condition,which is also confirmed by high-pressure experimental simulation.Based on petrological observation and high-pressure simulation,a polarized redox model of reducing slab but oxidizing mantle wedge in subduction zone is proposed,and its effect on deep carbon cycle in subduction zones is further discussed.  相似文献   

A synthesis of iron deposits in the eastern Tianshan,NW China     

《地学前缘(英文版)》2020,11(4):1271-1287

The northern Xinjiang region is one of the most significant iron metallogenic provinces in China.Iron deposits are found mainly within three regions:the Altay,western Tianshan,and eastern Tianshan orogenic belts.Previous studies have elaborated on the genesis of Fe deposits in the Altay orogenic belt and western Tianshan.However,the geological characteristics and mineralization history of iron deposits in the eastern Tianshan are still poorly understood.In this paper I describe the geological characteristics of iron deposits in the eastern Tianshan,and discuss their genetic types as well as metallogenic-tectonic settings,Iron deposits are preferentially distributed in central and southern parts of the eastern Tianshan.The known iron deposits in the eastern Tianshan show characteristics of magmatic Fe-Ti-V(e.g.,Weiya and Niumaoquan),sedimentary-metamorphic type(e.g.,Tianhu),and iron skarn(e.g.,Hongyuntan).In addition to the abovementioned iron deposits,many iron deposits in the eastern Tianshan are hosted in submarine volcanic rocks with well-developed skarn mineral assemblages.Their geological characteristics and magnetite compositions suggest that they may belong to distal skarns.SIMS zircon U-Pb analyses suggest that the Fe-Ti oxide ores from Niumaoquan and Weiya deposits were formed at 307.7±1.3 Ma and 242.7±1.9 Ma,respectively.Combined with available isotopic age data,the timing of Fe mineralization in the eastern Tianshan can be divided into four broad intervals:Early Ordovician-Early Silurian(476-438 Ma),Carboniferous(335-303 Ma),Early Permian(295-282 Ma),and Triassic(ca.243 Ma).Each of these episodes corresponds to a period of subduction,post-collision,and intraplate tectonics during the Paleozoic and Mesozoic time.  相似文献   

新疆东天山小白石头钨(钼)矿辉钼矿Re-Os同位素年龄及成矿时代   总被引：1，自引：0，他引：1  

李宁  杨富全  李超  张志欣  杨成栋 《岩矿测试》2019,38(1):112-122

小白石头钨(钼)矿床位于新疆东天山造山带中的中天山地块南缘,该矿床是一个由黑云母花岗岩和花岗闪长岩侵入中元古界卡瓦布拉格群形成的矽卡岩型钨(钼)矿床。辉钼矿作为其主要的矿石矿物之一,呈不同产出状态分布于花岗闪长岩、黑云母花岗岩、矽卡岩和石英脉中。目前,对于小白石头钨(钼)矿成矿时代尚有争议,特别是与花岗闪长岩有关的辉钼矿化形成时代缺乏精确的限定。本文选取与花岗闪长岩有关的不同产状辉钼矿进行Re-Os同位素定年,获得Re-Os加权平均模式年龄为245. 0±1. 7Ma,Re-Os等时线年龄为245. 5±4. 3Ma。准确的Re-Os同位素定年限定小白石头钨(钼)矿床的成矿年龄和花岗闪长岩的侵位年龄为245Ma左右,为矿床模型建立和找矿方向确定提供了关键依据,同时也为东天山区域成矿规律总结提供了重要的年代学证据,并指出新疆东天山—甘肃北山地区存在一条找矿潜力巨大的三叠纪钨钼成矿带。  相似文献   

天山南坡高冰川覆盖率的木扎提河流域水文过程对气候变化的响应   总被引：5，自引：5，他引：0  

赵求东  赵传成  秦艳  苌亚平  王建 《冰川冻土》2020,42(4):1285-1298

木扎提河是天山南坡冰川面积覆盖率最大（48.2%）的河流， 流域径流过程对气候变化极为敏感， 为了合理管理和规划水资源， 确保水资源的可持续利用， 亟需定量评估气候变化对该流域水文过程的影响。以VIC-CAS分布式水文模型为计算平台， 利用实测的径流和两次冰川编目间的冰川面积变化数据开展了模型的多目标参数化校正和验证， 有效提高了模拟结果的“真实性”， 然后通过数值模拟结果结合观测数据定量解析了流域径流的组成、 变化特征及对气候变化的响应机理。结果表明： 木扎提河总径流集中在暖季（5 - 9月）， 占全年总径流量的77.9%， 冰川径流、 融雪径流和降雨径流分别占总径流量的66.6%、 26.4%和7.0%。1971 - 2010年木扎提河流域气温和降水呈显著增加趋势， 由于降水的增加， 降雨和融雪径流均呈增加趋势， 但冰川径流呈现明显减少趋势， 导致总径流呈现下降趋势。在RCP4.5情景下， 未来该流域气温呈现明显升高趋势， 降水表现为微弱下降趋势； 气候变暖后， 更多降水以降雨形式发生， 未来降雨径流将明显增加， 降雪和融雪径流已于20世纪90年代达到峰值， 随后明显减少； 冰川面积将持续萎缩， 冰川径流于21世纪10年代达到拐点， 随后明显减少， 导致河道总径流量也将明显减少。  相似文献   

新疆天山地区壳幔S波速度结构特征及变形分析   总被引：1，自引：0，他引：1       下载免费PDF全文

蔡妍  吴建平  明跃红  房立华  王未来  孔祥艳  杨婷  范莉苹 《地球物理学报》2019,62(11):4214-4226

天山地区地质构造复杂，地震活动频繁，其壳幔变形和深部结构一直受到学者们的高度关注.然而，由于天山地区地震台站资料较少，致使壳幔变形研究结果与解释存在诸多争议.本研究利用在天山地区（40°N-46°N，78°E-92°E）新布设的11个流动宽频带地震台站和该地区39个固定台站的观测资料，采用接收函数与面波联合反演方法，获得了研究区地壳厚度及壳幔S波速度结构.反演结果显示天山地区（41.5°N-44°N，78°E-88°E）平均地壳厚度为56 km，塔里木盆地（40°N-41.5°N，79°E-90°E）、准噶尔盆地（44°N-46°N，82°E-90°E）和吐鲁番盆地（42°N-43°N，88°E-90°E）具有较厚的沉积层，地壳平均厚度为43 km、53 km和46 km，整体表现为天山厚、盆地相对较薄的特征；在研究区南天山的最高峰（42°N，80.5°E）及北天山的最高峰（43.5°N，86°E）附近，中下地壳存在较厚的低速层，我们认为在强烈挤压作用下低速、低强度的中下地壳强烈变形可能是导致该区域快速隆升的主要原因.在研究区中部，位于塔里木盆地与准噶尔盆地之间的天山地区，中下地壳及上地幔均存在低速层，且盆地莫霍面向天山倾斜明显.结合前人的研究成果推测，在南北向构造挤压应力作用下，塔里木盆地与准噶尔盆地发生了向天山造山带方向的双向壳幔层间插入俯冲.在研究区东部，塔里木盆地东北缘与天山东部接触带的地壳内没有明显的低速层，推测应处在早期挤压变形状态，该区域的壳幔边界为缓变的速度梯度带，可能与上地幔热物质侵入或渗透有关.  相似文献   

Ore Genesis and Tectonic Significance of the Xiaojiashan Tungsten Deposit,Eastern Tianshan,Xinjiang, China: Evidence from Geology,Fluid Inclusions,and Stable Isotope Geochemistry     

Yunfei Zhou  Jiuhua Xu  Lihua Shan  Xihui Cheng  Yueping Deng  Wenhuan Feng  Lingxiao Qiao 《Resource Geology》2019,69(1):43-64

The Xiaojiashan tungsten deposit is located about 200 km northwest of Hami City, the Eastern Tianshan orogenic belt, Xinjiang, northwestern China, and is a quartz vein‐type tungsten deposit. Combined fluid inclusion microthermometry, host rock geochemistry, and H–O isotopic compositions are used to constrain the ore genesis and tectonic setting of the Xiaojiashan tungsten deposit. The orebodies occur in granite intrusions adjacent to the metamorphic crystal tuff, which consists of the second lithological section of the first Sub‐Formation of the Dananhu Formation (D₂d ₁²). Biotite granite is the most widely distributed intrusive bodies in the Xiaojiashan tungsten deposit. Altered diorite and metamorphic crystal tuff are the main surrounding rocks. The granite belongs to peraluminous A‐type granite with high potassic calc‐alkaline series, and all rocks show light Rare Earth Element (REE)‐enriched patterns. The trace element characters suggest that crystallization differentiation might even occur in the diagenetic process. The granite belongs to postcollisional extension granite, and the rocks formed in an extensional tectonic environment, which might result from magma activity in such an extensional tectonic environment. Tungsten‐bearing quartz veins are divided into gray quartz vein and white quartz veins. Based on petrography observation, fluid inclusions in both kinds of vein quartz are mainly aqueous inclusions. Microthermometry shows that gray quartz veins have 143–354°C of T_h, and white quartz veins have 154–312°C of T_h. The laser‐Raman test shows that CO₂ is found in fluid inclusions of the tungsten‐bearing quartz veins. Quadrupole mass spectrometry reveals that fluid inclusions contain major vapor‐phase contents of CO₂, H₂O. Meanwhile, fluid inclusions contain major liquid‐phase contents of Cl^?, Na⁺. It can be speculated that the ore‐forming fluid of the Xiaojiashan tungsten deposit is characterized by an H₂O–CO₂, low salinity, and H₂O–CO₂–NaCl system. The range of hydrogen and oxygen isotope compositions indicated that the ore‐forming fluids of the tungsten deposit were mainly magmatic water. The ore‐forming age of the Xiaojiashan deposit should to be ~227 Ma. During the ore‐forming process, the magmatic water had separated from magmatic intrusions, and the ore‐bearing complex was taken to a portion where tungsten‐bearing ores could be mineralized. The magmatic fluid was mixed by meteoric water in the late stage.  相似文献