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1.
哈萨克斯坦阿克斗卡特大型斑岩铜矿床成矿时代与剥露历史研究 总被引:1,自引:0,他引:1
哈萨克斯坦阿克斗卡特大型斑岩型铜矿床产在中亚成矿域巴尔喀什成矿带阿克斗卡矿田。本文根据花岗岩类岩石的锆石U-Pb、40Ar/39Ar和裂变径迹(FT)热年代学研究,结合前人研究成果,给出了阿克斗卡斑岩铜矿床从深成岩浆活动、成矿作用、区域冷却到剥露作用的全过程。阿克斗卡矿床及附近花岗岩类锆石SHRIMPU-Pb定年结果,给出科尔达尔岩体早期英云闪长岩的结晶年龄为335.7±1.3Ma;主成矿期的含矿二长花岗斑岩结晶年龄为327.5±1.9Ma,反映了阿克斗卡矿床斑岩型铜成矿作用的年龄。花岗岩类角闪石、黑云母、钾长石40Ar/39Ar热年代学分别给出矿物冷却年龄为310.6Ma、271.5Ma和274.9Ma,进一步限定了深成斑岩型铜成矿作用的时代和区域冷却的历史。磷灰石FT测年数据揭示,受区域构造作用的影响,阿克斗卡铜矿田在晚白垩世(91~68.0Ma)发生地块的差异隆升和剥露作用。 相似文献
2.
中亚巴尔喀什成矿带萨亚克大型铜矿田矿床地质特征与成矿模式 总被引:2,自引:0,他引:2
综述了哈萨克斯坦巴尔喀什成矿带萨亚克大型铜矿田地质特征、矿田构造与成矿模式。萨亚克铜矿田是中亚成矿域巴尔喀什成矿带唯一的以矽卡岩型铜矿化为主的大型铜矿床,产在萨亚克地堑复向斜内。该矿田包括几个在空间上相对独立的矽卡岩型铜矿床、斑岩型铜钼网状脉矿床和一系列石英脉型矿脉,构成了斑岩型和矽卡岩型两个端元形成的成矿系列,但以矽卡岩型为主。矿床主要位于中石炭世灰岩与晚石炭世花岗岩类的接触带上,具有独特的矽卡岩型Cu-Au-Mo矿化组合,成矿时代为海西中晚期,根据本研究进行的锆石SHR I MP定年结果,主要与次要成矿期年龄分别为335±2Ma和308±10Ma。金属矿床主要赋存在地堑复向斜内局部发育的鞍状背斜顶部,部分富矿体的产出严格受断裂构造-岩浆活动的控制。闪长岩与铜矿化作用的关系最为密切,铜含量可高达1%以上;其次,花岗闪长岩与铜矿化的关系也较为密切,铜含量可达0.2%以上。萨亚克矽卡岩型铜矿田铜保有储量约为57.5万吨。 相似文献
3.
巴尔喀什成矿带是世界著名的中亚成矿域斑岩型铜钼成矿带, 产出许多斑岩型铜钼矿床和一些石英脉-云英岩型钨钼矿床.对巴尔喀什成矿带西部的东科翁腊德、阿克沙套、扎涅特3个典型的石英脉-云英岩型钼钨矿床的成矿时代和剥露过程进行了地质热年代学研究.锆石SHRIMP U-Pb定年给出东科翁腊德、阿克沙套、扎涅特与成矿作用有关的花岗岩类岩浆作用的时代分别为293.6±2.7 Ma、306±1 Ma和304±4 Ma, 属海西晚期构造-岩浆活动的产物.花岗岩类40Ar/39Ar测年结果给出了与成矿有关岩体的冷却年龄, 其等时线年龄分别为292±3 Ma(阿克沙套黑云母)、288.8±3.6 Ma(阿克沙套钾长石)和278±5 Ma(东科翁腊德钾长石).磷灰石裂变径迹测年给出东科翁腊德、阿克沙套、扎涅特的年龄分别为92.1±5.7 Ma、92.2±5.0 Ma和80.3±4.9 Ma, 说明这3个矿床的剥露作用主要发生在晚白垩世.花岗岩类岩石U-Pb、40Ar/39Ar和裂变径迹热年代学研究, 揭示了巴尔喀什成矿带Mo-W矿床从深成岩浆侵入活动、成矿作用、区域冷却到剥露作用的全过程. 相似文献
4.
相山铀矿田铀多金属成矿时代与成矿热历史 总被引:1,自引:1,他引:0
相山铀矿田的铀多金属矿化主要可划分为碱性铀矿化、酸性铀矿化、铅锌银铜矿化和金矿化四种类型。通过沥青铀矿和矿化岩石U-Pb等时线、黄铁矿Rb-Sr等时线、绢云母~(40)Ar-~(39)Ar同位素年龄测定,结合铀多金属成矿特征研究,厘定了相山铀矿田铀多金属成矿时代,确定铀多金属矿化的成矿时序为:碱性铀矿化、铅锌银铜矿化、金矿化、酸性铀矿化。锆石裂变径迹研究表明,相山矿田铀多金属矿化样品的锆石裂变径迹峰值年龄与U-Pb、Rb-Sr和~(40)Ar-~(39)Ar同位素年龄一致性良好,裂变径迹年龄(峰值年龄)可以限定热液铀多金属成矿热事件时代。碱性铀成矿热事件的锆石裂变径迹峰值年龄为119. 8~125. 6Ma;金成矿热事件和铅锌银铜多金属成矿热事件的锆石裂变径迹峰值年龄为106. 1~113. 8Ma;酸性铀成矿热事件的锆石裂变径迹峰值年龄为86. 7~100. 0Ma;新发现一期锆石裂变径迹峰值年龄为66. 4~78. 6Ma的热事件,该期热事件可能为相山矿田最晚一期酸性铀成矿热事件。相山矿田66. 4~78. 6Ma的铀成矿热事件,与华南花岗岩型热液铀矿床的区域成矿热事件时代耦合,该发现对华南火山岩型铀矿成矿时代的重新认识,对火山岩型、花岗岩型铀矿床成矿统一性认识具有重要意义。 相似文献
5.
通过对福建紫金山矿田深部与成矿作用有关的主期似斑状花岗闪长岩3组锆石SHRIMP U-Pb和2组角闪石、钾长石~(40)Ar/~(39)Ar测年,获得锆石~(206)Pb/~(238()U加权平均年龄为101.8±1.5 Ma(n=34,MSWD=1.0),代表紫金山矿田深部与成矿作用有关的主期似斑状花岗闪长岩的成岩年龄;同时获得角闪石~(40)Ar/~(39)Ar冷却年龄为100±11 Ma、102.2 Ma,钾长石的~(40)Ar/~(39)Ar冷却年龄为96.3±1.7 Ma、98.5 Ma。依据矿物封闭温度理论,估算紫金山矿田深部与成矿作用有关的主期似斑状花岗闪长岩由锆石结晶至角闪石40Ar/39Ar体系封闭、再到钾长石~(40)Ar/~(39)Ar体系封闭的岩石冷却速率分别是40.7~67.1℃/Ma、116.9~216.3℃/Ma,显示岩石的冷却速率较大;由古地温梯度推算主期似斑状花岗闪长岩结晶(101.8±1.5 Ma)至钾长石~(40)Ar/~(39)Ar体系封闭(96.3±1.7 Ma)期间岩体隆升剥露了约3 km,暗示地壳在这一时期发生了快速隆升剥蚀作用。紫金山矿田深部似斑状花岗闪长岩锆石206Pb/238U年龄佐证了紫金山矿田深部存在一个大岩基,并约束了紫金山矿田斑岩型矿床的成矿时代,单矿物的~(40)Ar/~(39)Ar年龄为矿区的隆升剥露研究提供新资料。 相似文献
6.
云南个旧是全球最大的锡铜多金属矿区,主要成矿作用是与燕山期花岗岩密切相关的岩浆-热液体系。矿区内铜矿的主要矿床类型为变玄武岩型层状铜矿和接触带型铜矿。赋存于花岗岩体的凹陷部位,接触带型铜矿体和氧化型矿体的精确年龄尚未有报道。以老厂矿田内与铜矿体同期的等粒花岗岩脉中的黑云母和与氧化矿同时形成的白云母作为研究对象,利用常规~(40)Ar/~(39)Ar同位素定年方法,获得了黑云母和白云母的~(40)Ar/~(39)Ar坪年龄分别为82.47±0.49Ma和76.17±0.42Ma,相应的正等时线年龄为82.38±0.48Ma和76.07±0.66Ma,反等时线年龄为82.38±0.49Ma和76.07±0.73Ma。结合野外地质接触关系和矿区内其他年代学结果认为,黑云母的~(40)Ar/~(39)Ar年龄82.38±0.48Ma可以代表接触带型铜矿体的形成年龄,也揭示了新山花岗岩体形成后的快速冷却作用过程;白云母的~(40)Ar/~(39)Ar年龄76.07±0.73Ma指示了氧化型矿体的形成年龄,也记录了矿区内与甲介山同期的南北向断裂的晚期活动时限。该年龄与个旧锡铜多金属矿床的成矿时代一致。 相似文献
7.
藏西措勤县日阿与斑(玢)岩有关的铜矿床的矿床地质特征与成矿时代 总被引:9,自引:0,他引:9
藏西地区措勤县日阿铜矿产于拉萨地块内,是一个与二长花岗斑岩岩株有关的矽卡岩型铜矿床。由矿体中金云母测得的40Ar/39Ar成矿年龄为(87.69±0.64)Ma,MSWD=0.42,与二长花岗斑岩的锆石U_PbSHRIMP年龄(90.1Ma)一致。同时,矿区内的辉绿玢岩脉,与二长花岗斑岩具有相近的年龄(87.2Ma)及相似的岩石地球化学特征,它们共同构成了一套含铜的双峰式岩石组合,代表了中—晚白垩世拉萨地块内的伸展构造环境下的铜成矿事件。文章指出,造成该矿区铜矿化的双峰式岩系(二长花岗斑岩—辉绿玢岩组合)是由班公湖—怒江洋壳向南俯冲,在碰撞后伸展阶段形成的。该矿床的发现表明,西藏高原除了与板块缝合带有关的斑岩型铜矿(包括玉龙、冈底斯、班公湖—怒江3条斑岩铜矿带)外,拉萨地块内部还有一期与双峰式岩系有关的斑岩_矽卡岩型铜矿成矿事件。 相似文献
8.
冈底斯中段尼木斑岩铜矿田的K-Ar、^40 Ar/^39 Ar年龄:对岩浆-热液系统演化和成矿构造背景的制约 总被引:7,自引:0,他引:7
青藏高原冈底斯斑岩成矿带不同于经典的产于岛弧和大陆边缘的斑岩铜矿,而形成于后碰撞挤压向伸展转变期,显示了极好的成矿前景。本文对冈底斯中段尼木矿田白容、厅宫和冲江斑岩铜矿区斑岩体进行了系统研究,确定出斑岩体演化和侵入序列为:似斑状二长花岗岩→成矿二长花岗斑岩→石英闪长玢岩→花岗闪长斑岩。K-Ar和~(40)Ar/~(39)Ar年代学研究获得白容矿区似斑状二长花岗岩中角闪石的K-Ar年龄为16.9±2.4Ma;石英闪长玢岩中黑云母的K-Ar年龄为12.3±0.2Ma、~(40)Ar/~(39)Ar坪年龄为12.5±0.2Ma;花岗闪长斑岩中黑云母的K-Ar年龄为11.5±0.2Ma、~(40)Ar/~(39)Ar坪年龄为12.4±0.2Ma;厅宫矿区石英闪长玢岩中黑云母的K-Ar年龄为13.8±0.2Ma、~(40)Ar/~(39)Ar坪年龄为14.9±0.2Ma;花岗闪长斑岩中黑云母的K-Ar年龄为13.5±0.3Ma、~(40)Ar/~(39)Ar坪年龄为14.2±0.2Ma,这些年龄表明:石英闪长玢岩晚于似斑状二长花岗岩,略早于花岗闪长斑岩。成矿与二长花岗斑岩有关,其侵位时间晚于似斑状二长花岗岩,早于石英闪长玢岩和花岗闪长斑岩。尼木斑岩铜矿田这种复式杂岩体较充分的分异演化有利于含矿热液的集中与逐渐富集成矿。白容斑岩铜矿蚀变矿化二长花岗斑岩的蚀变绢云母的K-Ar年龄为11.8±0.2Ma,~(40)Ar/~(39)Ar坪年龄为12.0±0.1Ma,代表了中低温蚀变和矿化末期的年龄。白容矿区绢云母化带的蚀变年龄与石英闪长玢岩和花岗闪长斑岩的黑云母~(40)Ar/~(39)Ar年龄基本一致,与厅宫矿区辉钼矿Re-Os年龄及石英闪长玢岩和花岗闪长斑岩的黑云母~(40)Ar/~(39)Ar年龄同样基本一致,暗示两个矿区石英闪长玢岩和花岗闪长斑岩的岩浆结晶冷却与成矿二长花岗斑岩后期热液成矿时间上有重叠。结合前人年龄数据大致确定出白容矿区岩浆-热液活动时限为0.5~5Ma,厅宫为4Ma,冲江为4.5Ma。尼木矿田成矿斑岩~(40)Ar/~(39)Ar年龄晚于冈底斯碰撞后第一次快速隆升时间≈21Ma,15Ma冈底斯中段NS向正断层开始活动,表明含矿斑岩体可能侵位于地壳加厚、冈底斯山大规模隆升到一定程度后出现弱伸展环境的构造背景下,即斑岩铜矿形成于从南北向挤压隆升到东西向伸展初始发育的过渡构造背景。 相似文献
9.
《西北地质》2014,(4)
青海省卡尔却卡铜多金属矿兼有斑岩-矽卡岩-热液系列的成矿特征,分A、B、C 3个区。其中A区主要为斑岩型成矿,B区为矽卡岩型矿化。铜多金属矿体主要产于花岗闪长岩、似斑状黑云母二长花岗岩体与寒武—奥陶纪滩间山群接触部位的矽卡岩带及似斑状二长花岗岩的斑岩矿化带中。笔者通过成矿岩体的岩石矿物组合和岩石地球化学特征对比,认为卡尔却卡B区的似斑状二长花岗岩的矽卡岩化成矿作用为早期的加里东俯冲碰撞阶段的产物。卡尔却卡矿区A区似斑状二长花岗岩的斑岩成矿作用和B区的花岗闪长岩矽卡岩成矿作用均是印支期晚期晚三叠世的大规模俯冲碰撞造山阶段的产物,构成了一个典型的斑岩型矿床成矿系统,叠加在早期的加里东期成矿作用上,形成了较大型的铜钼矿床。 相似文献
10.
采用激光显微探针40Ar/39Ar微区定年方法,对西藏邦铺钼铜多金属矿床中含矿脉石英进行微区年代测定,获得等时线年龄为13.9 Ma±0.9 Ma(MSWD=29),其下限(13 Ma)代表了成矿年龄。该年龄略晚于二长花岗斑岩结晶年龄(13.9 Ma±0.3 Ma,MSWD=3.05),表明邦铺矿床成岩成矿作用是一个连续的岩浆作用过程。同时对冈底斯斑岩铜矿带成岩-成矿年龄进行统计学研究,获得冈底斯斑岩铜矿带成岩-成矿作用高峰期为15 Ma,成岩-成矿年龄线性方程为Y岩=1.291X矿+7.785(R2=0.291),充分说明邦铺矿床与冈底斯斑岩铜矿一样,是一次大规模爆发成矿的过程,成矿事件发生具有高度的统一性与集中性。 相似文献
11.
Jiangyu Li Xuanhua Chen Zhihong Wang Wen Chen Chao Li Penghui Huang 《International Geology Review》2017,59(9):1131-1153
ABSTRACTThe West Junggar Metallogenic Belt (WJMB) is located between the Tianshan fault system and the Ertix fault system in the western part of the Central Asian Metallogenic Domain (CAMD). The belt features widespread late Palaeozoic granitic plutons, strike-slip faults, and porphyry copper and orogenic gold deposits. We collected nine molybdenite samples from the Baogutu III–IV Cu–Mo deposit and the Suyunhe Mo–W deposit, and 12 granitoid samples from the Jiaman, Kangde, Kulumusu, Bieluagaxi, Hatu, Akbastau, Miaoergou, Baogutu, Karamay, and Hongshan plutons in the WJMB. Molybdenite Re–Os dating gives metallogenesis ages of 312.7 and 299.7 Ma for the Baogutu III–IV and Suyunhe deposits, respectively. 40Ar/39Ar thermochronology yields biotite ages ranging from 326 to 302 Ma and K-feldspar ages from 297 to 264 Ma, indicating a regional medium-temperature cooling history in the WJMB during the late Carboniferous to middle Permian. By integrating these data with previous zircon U–Pb, amphibole 40Ar/39Ar, and zircon and apatite fission-track ages, we reconstruct the whole thermal history of the WJMB, which includes late Palaeozoic intrusive magmatism, porphyry Cu and W–Mo mineralization, and late Mesozoic tectonic uplift and exhumation of the WJMB. The regional 40Ar/39Ar cooling ages are consistent with the timing of regional sinistral strike-slip faulting, thereby indicating the tectonic significance of the cooling ages. We suggest that the biotite 40Ar/39Ar ages represent the static cooling of the granitic plutons after emplacement, since the ages are consistent with the U–Pb ages of the plutons. Thereafter, the oldest K-feldspar 40Ar/39Ar age may record the initiation of sinistral strike-slip movement on the Darabut, Mayile, and Baerluke faults. The regional faulting resulted in significant uplift of the WJMB during the early and middle Permian. 相似文献
12.
Guangming Li Kezhang Qin Kuishou Ding Tiebing Liu Jinxiang Li Shaohuai Wang Shanyuan Jiang Xingchun Zhang 《Resource Geology》2006,56(3):315-336
Abstract. Medium‐ and large‐scaled skarn Cu‐Au±Mo deposits, e.g. Kelu, Liebu, Chongmuda and Chenba among others, are distributed in Shannan area of the Gangdese Cu‐Au metallogenic belt. Intrusions‐related skarn copper mineralization belongs to high K and calc‐alkaline rock series, located in late collision volcano‐magmatic arc and formed between 20 to 30 Ma. Copper mineralization occurs at exocontact zone of the lower Cretaceous Bima Group carbonate and other calcareous‐bearing sedimentary rocks with intrusions. At present, three main mineralization types are identified, including skarn type, hydrothermal vein type and porphyry type. Mineralizing associations are Cu‐Mo, Cu‐Au and Cu. In ore districts, those mineralization types form an entire porphyry‐skarn Cu‐Au±Mo ore‐forming system. Alterations of the exocontact are mainly skarnization and hornfelsization, while the alterations of the endocontact are mainly sericitization, silicification, and chloritization of intrusion. In the study area, the endoskarn is not well developed. Copper mineralization occurs mainly in the exocontact in the form of stratoid, lenticular and pockety ore body. Veined mineralization can be seen in marblized and hornfelsed siltstone, being away from the contact zone. In the endocontact, the mineralization is mainly veinlet‐like and disseminated. In Shannan area, skarnization can be divided into early skarnization stage and late hydrous silicate stage. The early skarnization stage is featured by mainly andradite and grossular skarn, containing minor diopside, hedenbergite, magnetite and some copper minerals; and the late hydrous silicate stage is of replacement of garnet skarn by chlorite, epidote, quartz and calcite together with sulfides precipitation. The latter is the main stage of copper mineralization. Bornite is the dominant ore mineral associated with minor chalcopyrite and pyrite; and gold as well as silver are distributed in bornite and wittichenite. Results of microthermometry study of fluid inclusions in quartz of late hydrous silicate stage from different deposits show intermediate temperature and low to intermediate‐salinity features for all samples. The dominant inclusion type is composed of two phases, being about 4 to 15 % vapor and 85 to 96 % liquid at room temperature. Homogenization temperatures range from 232 to 335d?C. Salinities have been recorded between 4.2 and 15.5 wt% NaCl equivalent. Boiling fluid inclusions are not identified and it indicates that metal deposition mainly resulted from water‐rock reactions. The results of sulfur isotope analysis indicate that the sulfur isotope values (δ34S 1.29–1.68 %o) of the samples collected from skarns are similar with that from the endocontact (δ34S 1–1.75 %o). Both of them have very close sulfur isotope values (near δ34S 0 %o), which indicate the sulfur of both the skarn type and the porphyry type mineralization was from deep sources. Ages determined on biotite from ore‐bearing intermediate porphyries by Ar‐Ar methods range from 23.77±0.29 to 29.88±0.56 Ma, showing that skarn copper mineralization in the study area evidently is older than the porphyry Cu(‐Mo) mineralization in Gangdese, and likely representing another metallogenic event. The Cu‐Au skarn deposits in the Kelu‐Liebu‐Chongmuda belt are interpreted as the shallow level, skarn‐related deposits in a porphyry‐skarn mineralization. Appearance of porphyry copper mineralization in some skarn deposits implies that skarn copper mineralization of the study area resemble to those in northern sub‐metallogenic belt, having uniform porphyry‐skarn ore‐forming system. Therefore, it is presumed there should be potential to find deep level porphyry‐type Cu‐Au mineralization targets. 相似文献
13.
个旧卡房层状铜矿床金云母和云英岩化白云母40Ar-39Ar同位素年龄及意义 总被引:1,自引:0,他引:1
在个旧锡铜多金属矿集区发育有矽卡岩型和热液脉型等锡铜矿化体,其形成时代是晚白垩世,属与花岗岩有关的岩浆热液成因矿床。赋存于三叠纪蚀变玄武岩层中,呈(似)层状的铜矿体的精确年龄尚未有报道,成因仍备受争议。文章选择赋存于卡房矿田蚀变玄武岩层中,呈(似)层状分布的铜矿体中的金云母,及新山岩体接触带云英岩中的白云母为研究对象,利用40Ar-39Ar阶段加热同位素定年方法对它们进行了年代学研究,获得了金云母和白云母的40Ar-39Ar同位素坪年龄分别为(79.55±0.47) Ma和(79.53±0.57) Ma,对应等时线年龄分别为(79.8±1.3) Ma和(79.7±1.0) Ma,反等时线年龄分别为(79.7±2.0) Ma和(79.61±0.75) Ma,两者年龄基本一致。结合矿物共生组合特征和流体包裹体测温资料,认为金云母的坪年龄(79.55±0.47) Ma,可以代表卡房蚀变玄武岩中(似)层状铜矿的形成时代,而白云母的坪年龄(79.53±0.57) Ma,则代表新山岩体形成后期岩浆热液活动的年龄。这2个年龄与个旧锡铜多金属矿床的成矿时代基本一致,应是同一构造-岩浆-流体活动形成的成矿系列产物。 相似文献
14.
豫西银家沟硫铁多金属矿床Re-Os和40Ar-39Ar年龄及其地质意义 总被引:4,自引:1,他引:3
河南省银家沟硫铁多金属矿床位于华北克拉通南缘的华熊地块内,是东秦岭地区最大的硫铁多金属矿床,以其硫铁矿储量大及共、伴生元素复杂区别于东秦岭其他以钼为主的矿床.矿化在空间上呈规律性的带状分布,从岩体内向外,依次出现斑岩型钼矿体→斑岩型硫铁矿体→矽卡岩型铁矿体、钼矿体→矽卡岩型硫铁、铜、锌、金矿体→脉型铅、锌、银矿体.选取5件接触带矽卡岩型钼矿体中的辉钼矿样品进行Re-Os同位素定年,获得(142.9±2.1) Ma~(143.7±2.3) Ma的模式年龄,加权平均值为(143.4±0.9) Ma(MSWD=0.071),等时线年龄为(140.0±18.0) Ma(2σ,MSWD=0.095),将(143.4±0.9) Ma认作辉钼矿的结晶年龄,表明银家沟矿床矽卡岩型矿体形成于约143 Ma前;选取1件硅化、绢云母化、黄铁矿化、辉钼矿化钾长花岗斑岩中的绢云母样品定年,获得40Ar-39Ar坪年龄为(143.6±1.4) Ma,相应的39 Ar/36 Ar-40 Ar/39Ar等时线年龄为(143.0±2.0) Ma(MSWD=0.13),将(143.0±2.0)Ma认作绢云母的Ar封闭年龄,表明银家沟矿床斑岩型矿化亦发生在约143Ma前.本次辉钼矿Re-Os和绢云母40Ar-39A定年结果表明,银家沟矽卡岩型和斑岩型矿体均形成于早白垩世初期.银家沟矿床辉钼矿的ω(Re)在38.5×10-6~43.2×10-6之间,成矿物质主要来自由火成物质组成的宽坪群和二郎坪群,成矿与矿区内的钾长花岗斑岩有关.结合前人对东秦岭造山带中生代期间地球动力学背景的研究成果,笔者认为银家沟矿床形成于EW向构造体制向NNE向构造体制大转换阶段,即形成于挤压体制向伸展体制转换的背景. 相似文献
15.
《Geodinamica Acta》2013,26(5):267-282
The interaction of distinct geologic processes involved during late orogenic extensional exhumation history of the metamorphic units in the Eastern Rhodope is refined by new and reviewing 40Ar/39Ar geochronological and structural data. Minerals with different closure temperatures from metamorphic rocks investigated in this study are combined with those from magmatic and ore-forming hydrothermal rocks in two late stage metamorphic domes – the Kesebir-Kardamos and the Biala reka-Kehros domes. The 38-37 Ma muscovite and biotite cooling ages below 350°-300°C characterize basement metamorphic rocks that typified core of the Kesebir-Kardamos dome, constraining their exhumation at shallow crustal levels in the footwall of detachment. These ages are interpreted as reflecting last stage of ductile activity on shear zone below detachment, which continued to operate under low-temperature conditions within the semi-ductile to brittle field. They are close to and overlap with existing cooling ages in southern Bulgaria and northern Greece, indicating supportively that the basement rocks regionally cooled between 42-36 Ma below temperatures 350°-300°C. The spatial distribution of ages shows a southward gradual increase up structural section, suggesting an asymmetrical mode of extension, cooling and exhumation from south to the north at latitude of the Kesebir-Kardamos dome. The slightly younger 36.5-35 Ma crystallization ages of adularia in altered rocks from the ore deposits in the immediate hanging-wall of detachments are attributed to brittle deformation on high-angle normal faults, which further contributed to upper crustal extension, and thus constraining the time when alteration took place and deformation continued at brittle crustal levels. Silicic dykes yielded ages between 32-33 Ma, typically coinciding with the main phase of Palaeogene magmatic activity, which started in Eastern Rhodope region in Late Eocene (Priabonian) times. The 40Ar/39Ar plateau ages from the above distinct rock types span time interval lasting approximately ca. 6 Ma. Consequently, our geochronologic results consistently indicate that extensional tectonics and related exhumation and doming, epithermal mineralizations and volcanic activity are closely spaced in time. These new 40Ar/39Ar age results further contribute to temporal constraints on the timing of tectonic, relative to ore-forming and magmatic events, suggesting in addition that all above mentioned processes interfered during the late orogenic extensional collapse in the Eastern Rhodope region. 相似文献
16.
西藏冈底斯成矿带位于班公湖-怒江缝合带与雅鲁藏布江缝合带之间,从北向南依次可划分为3个成矿亚带:勒青拉-洞中松多铅锌银多金属成矿亚带,驱龙-甲马-邦铺斑岩铜钼成矿亚带,克鲁-冲木达斑岩-矽卡岩铜钼金成矿亚带。驱龙-甲马-邦铺成矿亚带内矿床的类型以斑岩型为主,部分伴生有矽卡岩型及热液脉型矿床。夏垅矿床位于驱龙-甲马-邦铺斑岩铜钼成矿亚带的西段,产于黑云母二长花岗岩基中,属于隐爆角砾岩型铅锌银多金属矿床。对夏垅矿床内与石英、方铅矿、闪锌矿密切共生的绢云母进行了40Ar-39Ar定年,确定其坪年龄及反等时线年龄分别为(23.56±0.22) Ma和(23.9±1.6) Ma。该矿床作为隐爆角砾岩型铅锌银多金属矿床的发现以及冈底斯火山岩自西向东逐渐变年轻的时空迁移规律说明在冈底斯成矿带的西侧存在着岩浆活动。夏垅矿床成矿年龄的精确测定把驱龙-甲马-邦铺斑岩铜钼成矿亚带向西延伸了120 km,增大了该成矿亚带的找矿潜力,为在该成矿亚带内寻找此类铅锌银多金属矿床提供了理论及实际依据。 相似文献
17.
The Balkhash Metallogenic Belt (BMB) in Kazakhstan, Central Asia, with the occurrence of the super-large Kounrad and Aktogai, the large Borly porphyry Cu–Mo deposits, and the large Sayak skarn polymetallic ore-field, is one of the central regions of the Paleozoic Central Asian metallogenic domain and orogenic belt. In this study, newly obtained SHRIMP zircon U–Pb ages of nine samples and 40Ar/39Ar ages of six mineral samples (inclding hornblende, biotite and K-feldspar) give more detailed constraints on the timing of the granitic intrusions and their metallogeny. Porphyritic monzonite granite and tonalite porphyry from the Kounrad deposit yield U–Pb zircon SHRIMP ages of 327.3 ± 2.1 Ma and 308.7 ± 2.2 Ma, respectively. Quartz diorite and porphyritic granodiorite from the Aktogai deposit yield U–Pb SHRIMP ages of 335.7 ± 1.3 Ma and 327.5 ± 1.9 Ma, respectively. Porphyritic granodiorite and granodiorite from the Borly deposit yield U–Pb SHRIMP ages of 316.3 ± 0.8 Ma and 305 ± 3 Ma, respectively. Diorite, granodiorite, and monzonite from the Sayak ore-field yield U–Pb SHRIMP ages of 335 ± 2 Ma, 308 ± 10 Ma, and 297 ± 3 Ma, respectively. Hornblende, biotite, and K-feldspar from the Aktogai deposit yield 40Ar/39Ar cooling ages of 310.6 Ma, 271.5 Ma, and 274.9 Ma, respectively. Hornblende, biotite, and K-feldspar from the Sayak ore-field yield 40Ar/39Ar cooling ages of 287.3 ± 2.8 Ma, 307.9 ± 1.8 Ma, and 249.8 ± 1.6 Ma, respectively. The new ages constrain the timing of Late Paleozoic felsic magmatism to ∼336 to ∼297 Ma. Skarn mineralization in the Sayak ore-field formed at ∼335 and ∼308 Ma. Porphyry Cu–Mo mineralization in the Kounrad deposit and the Aktogai deposit formed at ∼327 Ma, and in the Borly deposit at ∼316 Ma. The Late Paleozoic regional cooling in the temperature range of ∼600 °C to ∼150 °C occurred from ∼307 to ∼257 Ma. 相似文献