岩基后成矿作用:来自小兴安岭鹿鸣超大型钼矿的证据

小兴安岭鹿鸣钼矿是新近发现的斑岩型超大型钼矿.尽管近年有一些新年龄和新资料发表,但是关于矿区的成岩、成矿事件的时代和成因仍有很大争议.本文采用LA ICP-MS锆石U-Pb、辉钼矿Re-Os以及黑云母⁴⁰Ar-³⁹Ar等测年方法分别对矿区的花岗斑岩、辉钼矿、以及二长花岗岩(下文称鹿鸣花岗岩)中的黑云母开展年代学研究.结果显示矿区花岗斑岩形成于174.0±2Ma(MSWD=3.2);辉钼矿等时线年龄为177.8±2.3Ma(MSWD=0.078),辉钼矿模式年龄加权平均值为177.5±1.2Ma(MSWD=0.058).黑云母⁴⁰Ar-³⁹Ar 900~1400℃坪年龄为175.9±1.1Ma,表明鹿鸣花岗岩形成于约176Ma(之前).因此结合野外、岩相学、前人结果等,认为鹿鸣花岗岩岩基成岩在前(>176Ma),花岗斑岩成岩在后(约174Ma左右),成矿应当在花岗斑岩成岩近同时或稍后,为早侏罗世末期.花岗斑岩含有浸染状硫化物,表明花岗斑岩体是致矿侵入体,鹿鸣(二长)花岗岩岩基仅仅是钼矿的围岩.岩石地球化学特征,尤其是MgO含量较高,高Sr低Y等特征,以及构造环境判别显示鹿鸣花岗岩岩基和花岗斑岩形成于与俯冲有关的火山弧环境.在早侏罗世早-中期,该区在北部蒙古-鄂霍茨克海和东部的饶河、伊佐那崎洋联合汇聚下形成俯冲带之上的加厚地壳,此时与地幔楔发生过反应的幔源岩浆底侵产生广泛的壳幔相互作用,形成鹿鸣花岗岩的岩基.随后加厚下地壳拆沉导致鹿鸣花岗岩岩基快速隆升,在地壳浅部,与来自于深部的花岗斑岩岩浆(+钼矿和深部流体)相遇,后者侵入到鹿鸣花岗岩岩基中,形成了斑岩及辉钼矿矿床.据此,提出鹿鸣钼矿属于岩基后成矿作用的产物.     

Chronology,geochemistry and Sr–Nd isotope studies of Jurassic intrusions in the Diyanqinamu porphyry Mo mine,central Inner Mongolia,China

Available cores of porphyritic granite and aplitic granite from the Diyanqinamu porphyry Mo deposit in the north central Great Xing’an Range presented an opportunity to examine and analyze Mesozoic igneous rocks far from the Paleo-Pacific subduction zone. The Diyanqinamu granites are highly fractionated I-type, distinguished from the M-, A- or S-type granite by: high SiO₂, and Rb; low Zr, Nb, Y, and Ce; low Fe₂O₃^total/MgO and (K₂O + Na₂O)/CaO ratios; low alumina saturation index (<1.1); low initial I_Sr ratios (0.70137–0.70451); positive εNd(t) values (2.37–3.77); and negative correlation between P₂O₅ and SiO₂. The aplitic granites were generated by fractional crystallization of the porphyritic granite, as evidenced by: spatial proximity; consistent zircon U–Pb ages (156 Ma) within error; correlations between other oxides and SiO₂ in Haker diagrams; low Ba, Sr, Nb, P, Ti, Eu; linear relationship in both (La/Yb)_N vs. La and Sr vs. Ba diagrams; and, decreasing LREE and ∑REE with increasing SiO₂. The Diyanqinamu granites have young depleted-mantle two-stage model ages (avg. T_DM2 = 660 Ma) similar to those of most Mesozoic voluminous felsic magmas in northeastern China, and were likely sourced from pre-existent crustal components both “old” and juvenile that had been juxtaposed during the tectonic evolution of the Paleo-Asian Ocean. These granites project in the transitional field from syn-collision to post-collision tectonic settings on tectonic discrimination diagrams, implying emplacement in an extensional environment. Extensional volcanism and basin formation in the Great Xing’an Range region in Late Jurassic is coeval with the Diyanqinamu granites, demonstrating that post-orogenic lithospheric extension related to the closure of the Mongol-Okhotsk Ocean was the main driving force for Late Jurassic magmatism in this region.     

Late Pleistocene climate inferred from the reconstruction of the Taylor River glacier complex, southern Sawatch Range, Colorado

Ice surface topography of a late Pleistocene glacier complex, herein named the Taylor River Glacier Complex (TRGC), was reconstructed on the basis of detailed mapping of glacial landforms combined with analyses of aerial photos and topographic maps. During the last glacial maximum (LGM), the TRGC covered an area of 215 km² and consisted of five valley or outlet glaciers that were nourished by accumulation in cirques basins and/or upland ice fields.Equilibrium-line altitudes (ELAs) for the glaciers of the TRGC were estimated using the accumulation-area ratio method, assuming that ratio to be 0.65 ± 0.05. ELAs thus derived ranged from about 3275 to 3400 m, with a mean of 3340 ± 60 m. A degree-day model (DDM) was used to infer the climatic significance of the LGM ELA. With no appreciable differences in precipitation with respect to modern climate, the ELA implies that mean summer temperatures during the LGM were 7.6 °C cooler than today. The DDM was also used to determine the temperatures required to maintain steady-state mass balances for each of the reconstructed glaciers. The required reductions in summer temperature vary little about a mean of 7.1 °C. The sensitivity of these results to slight (± 25%) changes assumed for LGM precipitation are less than ± 0.5 °C. Even under an LGM climate in which precipitation is assumed to be substantially different (± 50%) than the present, mean summer temperatures must be on the order of 7.0 to 8.5 °C lower to depress equilibrium lines to LGM altitudes. The greater sensitivity of the ELA to changes in temperature suggests that glaciation in the region was driven more by decreases in summer temperature rather than increases in precipitation.     

Geomorphic inferences from regolith thickness, chemical denudation and CRN erosion rates near the glacial limit, Boulder Creek catchment and vicinity, Colorado

Granitic regolith, developed in the Boulder Creek catchment and adjacent areas, records a history of deep weathering, some of which may predate Quaternary time. Field and well-log measurements of weathering, chemical denudation and rates of erosion derived from ¹⁰Be cosmogenic radionuclide (CRN) data help to quantify rates of landscape change in the post-orogenic Rocky Mountains. The density of oxidized, fractured bedrock ranges from 2.7 to about 2.2 g cm^− 3, saprolite and grus have densities between 2.0 and 1.8 g cm^− 3, and 30 soil samples averaged 1.6 ± 0.2 g cm^− 3. Highly weathered regolith in 540 wells averages 3.3 m thick, mean depth to bedrock in 1661 wells is 7 m, and the weathered thickness exceeds 10 m in relatively large local areas east of the late Pleistocene glacial limit. Thickness of regolith shows no simple relationship to rock type or structure, local slope, or distance from channels. Catchments in the vicinity of the Boulder Creek have an average CRN erosion rate of 2.2 ± 0.7 cm kyr^− 1 for the past 10,000 to 40,000 yr. Annual losses of cations and SiO₂ vary from about 2 to 5 g m^− 2 over a runoff range of 10 to nearly 160 cm.Using measured rates in simple box models shows that if a substantial fraction of void space is created by volume expansion in the weathering rock materials, 7 m of weathered rock materials could form in as little as 230 kyr. If density loss results mainly from chemical denudation and some volume expansion, however, the same weathering profile would take > 1340 kyr to form. Rates of erosion measured by CRN could be balanced by the rate of soil formation from saprolite if the annual solute loss from soil is 2.0 g m^− 2 and 70% of the density decrease from saprolite to grus and soil results from strain. Saprolite, however, forms from oxidized bedrock at a far slower rate and rates of saprolite formation cannot balance soil and grus losses to erosion. The zone of thick weathered regolith is likely an eroding relict landscape. The undulating surface marked by relatively low relief and tors is not literally a topographic surface of Eocene, Oligocene or Miocene age unless it was covered with deposits that were removed in Pliocene or Quaternary time.     

Zircon U-Pb geochronology and geochemistry of the intrusions associated with the Jiawula Ag-Pb-Zn deposit in the Great Xing’an Range,NE China and their implications for mineralization

Located in the eastern section of the Central Asian Orogenic Belt, the Jiawula Ag-Pb-Zn deposit is classified as a volcanic to subvolcanic related vein-type ore deposit. New U-Pb zircon geochronology, whole-rock geochemistry, mineral chemistry, and Sr-Nd isotope data are presented for the intrusions in the Jiawula deposit in order to evaluate the timing, petrogenetic type of the granitoid rocks, origin and evolution of magmatism, geodynamics, and to establish its relationship with lead-zinc mineralization. Zircon SHRIMP U-Pb analyses yield weighted mean ages of 150.1 ± 1.8 Ma for quartz porphyry, 148.8 ± 2.2 Ma for syenite porphyry, and 145.3 ± 1.9 Ma for monzonite porphyry, indicating a Late Jurassic (Yanshanian) magmatic event. An earlier magmatic event (Indosinian) occurred during the Late Permian to Early Triassic from ca. 254 Ma to ca. 247 Ma and is represented by granodiorite (254 ± 2 Ma), dacite porphyry (252.9 ± 4.8 Ma), and diorite porphyry (278 ± 4.1 Ma). Both the Indosinian and Yanshanian igneous rocks are classified as I-type granitoids. The late Jurassic intrusions are highly fractionated and characterized by negative anomalies of Eu, Sr, P, and Ti. The hypabyssal intrusions have initial ⁸⁷Sr/⁸⁶Sr values between 0.70458 and 0.70522, and ε_Nd(t) values of −3.4 to −0.2, indicating relatively older crust in Jiawula among more juvenile crust in this area. Magma generation in Jiawula is linked to juvenile lower crustal and slightly enriched mantle sources. The ∼250 Ma magmatic episode in Jiawula might be related to the subduction of the Mongol-Okhotsk oceanic plate towards the south beneath the Erguna massif. The ∼150 Ma magmatic event occurred after the closure of the Mongol-Okhotsk Ocean followed by the change in subduction direction of the Paleo-Pacific plate. Varying temperature, stronger fractionation and higher oxygen fugacity related to the magmatic-hydrothermal transition caused Pb-Zn mineralization.     

Paleomagnetism and U–Pb geochronology of the Black Range dykes,Pilbara Craton,Western Australia: a Neoarchean crossing of the polar circle

We report a new paleomagnetic pole for the Black Range Dolerite Suite of dykes, Pilbara craton, Western Australia. We replicate previous paleomagnetic results from the Black Range Dyke itself, but find that its magnetic remanence direction lies at the margin of a distribution of nine dyke mean directions. We also report two new minimum ID-TIMS ²⁰⁷Pb/²⁰⁶Pb baddeleyite ages from the swarm, one from the Black Range Dyke itself (>2769 ± 1 Ma) and another from a parallel dyke whose remanence direction lies near the centre of the dataset (>2764 ± 3 Ma). Both ages are slightly younger than a previous combined SHRIMP ²⁰⁷Pb/²⁰⁶Pb baddeleyite weighted mean date from the same swarm, with slight discordance interpreted as being caused by thin metamorphic zircon overgrowths. The updated Black Range suite mean remanence direction (D = 031.5°, I = 78.7°, k = 40, α₉₅ = 8.3°) corresponds to a paleomagnetic pole calculated from the mean of nine virtual geomagnetic poles at 03.8°S, 130.4°E, K = 13 and A₉₅ = 15.0°. The pole's reliability is bolstered by a positive inverse baked-contact test on a younger Round Hummock dyke, a tentatively positive phreatomagmatic conglomerate test, and dissimilarity to all younger paleomagnetic poles from the Pilbara region and contiguous portions of Australia. The Black Range pole is distinct from that of the Mt Roe Basalt (or so-called ‘Package 1’ of the Fortescue Group), which had previously been correlated with the Black Range dykes based on regional stratigraphy and imprecise SHRIMP U–Pb ages. We suggest that the Mt Roe Basalt is penecontemporaneous to the Black Range dykes, but with a slight age difference resolvable by paleomagnetic directions through a time of rapid drift of the Pilbara craton across the Neoarchean polar circle.     

北天山中东段中小地震震源机制解及应力场反演

主要对北天山中东段中小地震震源机制解系统聚类和应力场反演。 结果表明, 研究区内中小地震震源断错性质主要以逆断层为主, 地震主破裂面基本沿NWW向或近EW向, 与该区域的NWW向构造带基本一致; 研究区内主压应力P轴近NS向, 倾角较小, 主张应力T轴倾角较大, 表明区域应力场主要受NS向水平挤压作用; 分区应力场反演结果显示, 研究区中、 西部最大主应力方向为近NS向, 与北天山西段构造应力场方向相一致。     

吉林-黑龙江高压变质带的初步厘定:证据和意义

本文定义的吉林-黑龙江高压变质带是指我国东北地区佳木斯-兴凯地块西缘和南缘共同发育的呈弧形展布的高压变质带,具体包括佳木斯-兴凯地块西缘增生杂岩带(黑龙江蓝片岩带和张广才-小兴安岭增生杂岩带)和佳木斯-兴凯地块南缘的长春-延吉增生杂岩带.其中佳木斯-兴凯地块西缘增生杂岩带形成于晚三叠-早侏罗世(180 ～ 210Ma),为佳木斯-兴凯地块向西冲增生而形成的高压变质带;而长春-延吉增生杂岩带由一系列特征性俯冲-增生杂岩组成,包括石头口门-烟筒山红帘石片岩带、呼兰群变质杂岩、色洛河群变质杂岩、青龙村群变质杂岩和开山屯变质杂岩等,形成时代为187～230Ma,峰期为220～230Ma.长春-延吉增生杂岩带曾被认为是西拉木伦河断裂带的东延部分,但是区域构造分析表明,它们形成的动力学背景与佳木斯-兴凯地块西缘增生杂岩带相同,均为太平洋板块三叠纪-早侏罗世的西向俯冲导致佳木斯-兴凯地块自东向西的“剪刀式”闭合过程.我们将佳木斯-兴凯地块西缘和南缘发育的三叠纪-早侏罗世增生杂岩带作为统一的构造单元来考虑,结合该区发育有典型的高压变质带,因此命名为“吉林-黑龙江高压变质带,简称吉黑高压带”.吉黑高压带形成于太平洋板块三叠纪-早侏罗世的西向俯冲导致佳木斯-兴凯地块自东向西的“剪刀式”闭合的过程,同时该带记录了古亚洲构造域的结束和太平洋俯冲开始的关键时期,为两大构造域叠加与转换的关键性地质证据.     

大兴安岭植被NDVI变化及其对气候的响应

利用S-G(Savitsky-Golay)滤波对2000—2016年呼伦贝尔市境内的大兴安岭植被NDVI序列进行逐栅格重构并剔除突变点,结合大兴安岭海拔、坡向、坡度等地理因子和气温、降水等气象因子,分析大兴安岭植被生长季NDVI的变化及其对气候的响应。结果表明:大兴安岭植被NDVI生长季均值呈上升趋势,平均增速为0. 029/10 a。植被NDVI随海拔的增加呈现先缓慢减小后迅速增加的趋势,随坡向变化不大,随坡度的增加而增加。植被NDVI的生长季均值与1 a前和2 a年前的降水呈现显著的正相关,具有明显的滞后性。在每年植被恢复生长初期各海拔植被均与气温呈现极显著的正相关,年内植被NDVI与降水的相关性在垂直方向上存在较大差异。     

DERF2.0模式对贵州延伸期、月预测质量对比分析

利用2014—2016年第二代月动力延伸预测模式业务系统(DERF2. 0)直接输出及预报员预报的贵州省气温和降水预报数据、贵州省84站观测数据,采用Ps、Cs和Zs 3种评分方法评估了DERF2. 0对贵州月气温、降水和月内强降水过程的预测性能,并与预报员业务值班发布的预报质量进行对比分析,系统性地对DERF2. 0产品在延伸期/月尺度的预测效果进行检验评估。结果表明:DERF2. 0月预测产品总体上对贵州气温的预测性能优于降水,气温偏高预测的可参考性高于其对气温偏低的预测。DERF2. 0预报月气温的Ps评分较预报员略高,月降水较预报员略低,总体来看DERF2. 0月预测效果较预报员综合预报略差且预报性能较不稳定。预报员预测数据的Zs和Cs评分总体高于DERF2. 0预测数据,但DERF2. 0预测数据的Zs和Cs评分较预报员逐年提高,尤其在整个雨季时段较为明显。DERF2. 0对主汛期(6—8月)的预报准确率较整个雨季期(4—10月)略高。