冈底斯印支期造山事件:花岗岩类锆石U-Pb年代学和岩石成因证据

对冈底斯中部地区二云母花岗岩和花岗闪长岩进行了LA-ICP-MS锆石U-Pb定年、主量元素、微量元素和锆石Hf同位素组成的测定.结果表明, 二云母花岗岩的岩浆结晶年龄为(205± 1)Ma, 岩石属于强过铝质花岗岩, A/CNK= 1.16~ 1.20, K₂O/Na₂O= 1.67~ 1.95.岩石富Rb、Th和U等元素, Eu/Eu* = 0.29~ 0.41, (La/Yb)_N= 22.62~ 35.08.锆石ε_Hf(t)= -12.4~ -1.8.二云母花岗岩的岩浆产生于地壳中泥质岩类在无外来流体加入的情况下云母类矿物脱水反应所诱发的部分熔融作用, 其岩石形成机制类似于喜马拉雅新生代淡色花岗岩.花岗闪长岩的岩浆结晶年龄为(202± 1)Ma, 岩石属于准铝质(A/CNK= 0.96~ 0.98), K₂O/Na₂O= 1.42~ 1.77, Eu/Eu* = 0.54~ 0.65, (La/Yb)_N= 6.76~ 13.35.锆石ε_Hf(t)= -8.2~ -5.5.根据花岗闪长岩的地球化学特征和锆石Hf同位素组成, 花岗闪长岩的岩浆来自于地壳中基性岩类的部分熔融.冈底斯印支晚期强过铝质花岗岩的确定, 表明了冈底斯在印支晚期以前曾发生地壳的缩短与加厚作用, 从而进一步明确了冈底斯印支早期的造山事件及冈底斯经历了多期造山作用的演化.      

Early Paleoproterozoic magmatism in the Quanji Massif, northeastern margin of the Qinghai-Tibet Plateau and its tectonic significance: LA-ICPMS U-Pb zircon geochronology and geochemistry

The Quanji Massif is located on the north side of the Qaidam Block and is interpreted as an ancient cratonic remnant that was detached from the Tarim Craton. There are regionally exposed granitic gneisses in the basement of the Quanji Massif whose protoliths were granitic intrusive rocks. Previous studies obtained intrusion ages for some of these granitic gneiss protoliths. The intrusion ages span a wide range from ~ 2.2 Ga to ~ 2.47 Ga. This study has determined the U-Pb zircon age of four granitic gneiss samples from the eastern, central and western parts of the Quanji Massif. CL images and trace elements show that the zircons from these four granitic gneisses have typical magmatic origins, and experienced different degrees of Pb loss due to strong metamorphism and deformation. LA-ICPMS zircon dating yields an upper intercept age of 2381 ± 41 (2σ) Ma from monzo-granitic gneiss in the Hudesheng area and 2392 ± 25 (2σ) Ma from granodioritic gneiss in the Mohe area, eastern Quanji Massif, and 2367 ± 12 (2σ) Ma from monzo-granitic gneiss in the Delingha area, central Quanji Massif, and 2372 ± 22 (2σ) Ma from monzo-granitic gneiss in the Quanjishan area, western Quanji Massif. These results reveal that the intrusive age of the protoliths of the widespread granitic gneisses in the Quanji Massif basement was restricted between 2.37 and 2.39 Ga, indicating regional granitic magmatism in the early Paleoproterozoic, perhaps related to the fragmentation stage of the Kenorland supercontinent. Geochemical results from the granodioritic gneiss from the Mohe area indicate that the protolith of this gneiss is characterized by adakitic rocks derived from partial melting of garnet-amphibolite beneath a thickened lower crust in a rifting regime after continent-continent collision and crustal thickening, genetically similar to the TTG gneisses in the North China Craton. This suggests that the Quanji Massif had a tectonic history similar to the Archean Central Orogenic Belt of North China Craton during the early Paleoproterozoic. We tentatively suggest that the Quanji Massif and the parental Tarim Craton and the North China Craton experienced rifting in the early Paleoproterozoic, after amalgamation at the end of the Archean. The Tarim Craton and North China Craton might have had close interaction from the late Neoarchean to the early Paleoproterozoic.     

太平洋西北平顶海山上环礁型碳酸盐建造与白垩纪赤道洋流

深海钻探揭示构成环礁的浅水碳酸盐建隆覆盖沉积在太平洋西北部平顶海山之上。相对于现今珊瑚藻类生物构成的环礁而言,白垩纪和古新世孤立的环礁的四周边缘生物含量甚少,造礁能力下降。这些环礁浅水碳酸盐沉积在火山基座的顶部,在Albian初期、Albian末期、Maastrichtian晚期和始新世中期发生沉没。早期研究认为这些碳酸盐体系经历了地面暴露阶段以及随后的海侵淹没阶段。然而,一个事实是,环礁沉没仅发生在当太平洋板块背负着平顶海山向北漂移过程中,并且是经过南纬7°以后。几个不同的假说用来解释该时期环礁沉没现象,包括环礁暴露、喀斯特化、地面侵蚀、增强赤道上升洋流、缺氧和/或者富营养的浑浊水的出现等。文中在太平洋平顶海山深海钻孔的沉积、生物地层和古纬度数据综合研究基础上,提出一种新模式用于解释晚白垩世—古新世浅水碳酸盐建造的沉没。与以前的模式不同的是,文中提出,这些晚白垩世—古新世“环礁”之所以发生沉没,原因是受到原始环南赤道洋流(pSEC)的影响,导致一种对分泌碳酸盐的生物不利环境的产生。而且,当这些平顶海山漂移到南纬5°时,即赤道古纬度带,许多浅水碳酸盐建造之上,铁锰结核开始沉积。同时,平顶海山下沉到溶解氧极小层(海平面之下400~1 100 m)和原始环南赤道中层洋流( pEI     

Sm–Nd and Ar–Ar Isotopic Dating of the Nuri Cu–W–Mo Deposit in the Southern Gangdese,Tibet: Implications for the Porphyry‐Skarn Metallogenic System and Metallogenetic Epochs of the Eastern Gangdese

The Nuri Cu–W–Mo deposit is a large newly explored deposit located at the southern margin of the Gangdese metallogenic belt. There are skarn and porphyry mineralizations in the deposit, but the formation age of the skarn and the relationship between the skarn and porphyry mineralizations are controversial. Constraints on the precise chronology are of fundamental importance for understanding the ore genesis of the Nuri deposit. To determine the formation age of the skarn, we chose garnets and whole rock skarn samples for Sm–Nd dating. We also selected biotite associated with potassic alteration for Ar–Ar dating to confirm the ore formation age of the porphyry mineralizations. The Sm–Nd ages of the skarn are 25.73 ± 0.92 – 25.2 ± 3.9 Ma, and the age of the potassic alteration is 24.37 ± 0.32 Ma. The results indicate that the skarn and porphyry mineralization are coeval and belong to a unified magmatic hydrothermal system. Combined with a previous molybdenite Re–Os age, we think that the hydrothermal activity of the Nuri deposit lasted for 1.2 – 2.1 Myr, which indicates that the mineralization formed rapidly. The chronologic results indicate that the Nuri deposit formed in the period of transformation from compression to extension in the late collisional stage of the collision between the Indian and Eurasian continents.     

碰撞前印度大陆北缘古地理轮廓——藏南晚白垩世堆拉灰岩古地磁研究

堆拉灰岩的古地磁数据为重建碰撞前印度大陆北缘轮廓提供了重要制约,但也留下了一些疑点,为此,本文对该地区晚白垩世海相沉积开展了进一步的古地磁研究。通过对10个采点样品的系统退磁及统计分析,得到宗山组最下段经地层校正后的特征剩磁分量为D=168.2°,I=-7.3°,α95=7.5°。该分量与前人从该地区宗山组中、上段得到的古地磁结果无显著区别,并在95%的置信水平上通过褶皱检验,表明剩磁是褶皱前获得的。尽管如此,堆拉晚白垩世灰岩统一的负极性特征与其沉积期间(Turonian-Maastrichtian)对应的古地磁标准极性柱不符,表明该地区宗山组不同层位可能普遍遭遇了重磁化,不能用来约束喜马拉雅地体的古地理位置。基于以上考虑,本文仅用前人从岗巴宗山地区获得的古地磁结果对晚白垩世期间特提斯喜马拉雅地体的古地理位置进行了计算和修正,结果显示该地体在宗山组上段沉积期间(约71~65Ma)的古纬度约为9°S,计算得到当时大印度的北向延伸量为1500km,与前人从宗浦组得到的古地磁结果一致。     

中部崛起背景下的郑汴一体化发展研究

中部地区崛起战略决策,为中原城市群发展提供了良好的发展环境,也提出了重大而迫切的战略任务.在中原城市群各个城市处于向心集聚为主的发展阶段,中原城市群建设应率先推进郑汴核心区一体化发展.郑汴核心区既是郑汴一体化的空间承载区,也是中原城市群一体化发展的先导区和示范区,需要从发展目标协同、基础设施共建、产业互补共进、资源共事、发展空间与功能协调、实施策略同步等多个方面有序促进郑汴一体化发展.     

西藏冈底斯东段帮浦铜多金属矿床成矿流体特征

为了探讨西藏冈底斯斑岩铜矿带帮浦铜多金属矿床流体的来源及演化过程,对矿体中的石英斑晶、辉钼矿石英脉、铅锌矿石英脉及方解石脉中所含的流体包裹体进行了岩相学、显微测温和激光拉曼探针以及硫同位素研究。结果表明:与成矿有关的流体包裹体可以分为富气相包裹体、富液相包裹体、含子晶多相包裹体3个类型。流体包裹体的均一温度、盐度及密度测定值均可分为两个区间,分别为300~350℃、390~440℃,6.96~11.63 wt%NaCl、16.76~23.7wt%NaCl及1.05~1.15g/cm3、0.40~1.00 g/cm3。含石盐子晶包裹体所对应的盐度范围是39.38~56.1wt%NaCl。激光拉曼光谱分析表明,含子晶流体包裹体中子矿物为石盐、黄铜矿、白铁矿等,气相包裹体和液相包裹体中气相中含有CO2。石英斑晶与辉钼矿石英脉中低密度气相包裹体与高密度液相包裹体、高盐度含子晶包裹体共生,其均一温度范围一致,但盐度相差较大,指示成矿流体有不混溶作用或沸腾作用,成矿流体来自于岩浆的出熔,金属硫化物直接来源于岩浆;而铅锌矿石英脉与两种不同性质流体的混合作用有关。     

Classification of seamount morphology and its evaluating significance of ferromanganese crust in the central Pacific Ocean

1 IntroductionCobalt-richcrust, alsoknownasferrom anganesecrustormanganesecrust, isdefined astheferroman-ganesedepositiondistributingontheseamountandoc-curringinlayer,crustandgravelornoduleinpart.Itisrich inthemetalofhigh economicvalue(cobalt,nick-el,plat…     

Pseudosection modelling and garnet Lu–Hf geochronology of HP amphibole schists constrain the closure of an ocean basin between the northern and southern Lhasa blocks,central Tibet

The P–T–t path of high‐P metamorphic rocks in subduction zones may reveal valuable information regarding the tectonic processes along convergent plate boundaries. Herein, we present a detailed petrological, pseudosection modelling and radiometric dating study of several amphibole schists of oceanic affinity from the Lhasa Block, Tibet. The amphibole schists experienced an overall clockwise P–T path that was marked by post‐P_max heating–decompression and subsequent isothermal decompression following the attainment of peak high‐P and low‐T conditions (~490°C and 1.6 GPa). Pseudosection modelling shows that the amphibole schists underwent water‐unsaturated conditions during prograde metamorphism, and the stability field of the assemblage extends to lower temperatures and higher pressures within the water‐unsaturated condition relative to water‐saturated model along the prograde path. The high‐P amphibole schists were highly reduced during retrograde metamorphism. Precise evaluation of the ferric iron conditions determined from the different compositions of epidote inclusions in garnet and matrix epidote is crucial for a true P–T estimate by garnet isopleth thermobarometry. Lu–Hf isotope analyses on garnet size separates from a garnet‐bearing amphibole schist yield four two‐point garnet–whole‐rock isochron ages from 228.2 ± 1.2 Ma to 224.3 ± 1.2 Ma. These Lu–Hf dates are interpreted to constrain the period of garnet growth and approximate the timing of prograde metamorphism because of the low peak metamorphic temperature of the rock and the well‐preserved Mn/Lu growth zoning in garnet. The majority of zircon U–Pb dates provide no constraints on the timing of metamorphism; however, two concordant U–Pb dates of 222.4 ± 3.9 Ma and 223.3 ± 4.2 Ma were obtained from narrow and uncommon metamorphic rims. Coexistence of zircon and sphene in the samples implies that the metamorphic zircon growth was likely assisted by retrogression of rutile to sphene during exhumation. The near coincident radiometric dates of zircon U–Pb and garnet Lu–Hf indicate rapid burial and exhumation of the amphibole schists, suggesting a closure time of c. 224–223 Ma for the fossil ocean basin between the northern and southern Lhasa blocks.