藏北多龙矿集区地壳基底性质、演化及其对成矿的制约——来自波龙火山-侵入岩中继承锆石U-Pb年龄的信息

地壳基底性质及其演化对区域金属成矿类型和成矿潜力具有重要影响。藏北多龙矿集区是目前中国规模最大的斑岩-浅成低温热液型铜多金属矿集区之一,其地壳基底性质与演化缺少研究,制约了对区内铜多金属成矿构造背景和成矿物质来源的全面认识。多龙矿集区内波龙火山-侵入岩中继承锆石LA-ICP-MS U-Pb测年结果显示,14颗继承锆石具有新太古代—古元古代年龄(2581~1670Ma),这些锆石多为自形-半自形颗粒,具有原地来源的特征,表明多龙矿集区深部存在新太古代—古元古代结晶基底。该基底应该是南羌塘中心地区古老基底向南延伸的一部分。该基底在中元古代—早古生代遭受多次构造-岩浆热事件改造,尤以泛非期—早古生代最强烈。进入晚中生代后,由于年轻地幔物质的加入,多龙地壳发生明显的垂向生长,形成富含金属和成矿组分的新生下地壳,该新生下地壳在早白垩世发生活化,为多龙成矿体系提供大量的金属及其他幔源有用组分。多龙矿集区是一个"两期岩浆叠加成矿"的典型例子。     

西藏松多地区晚白垩世末期弧岩浆岩岩石成因及构造意义

新特提斯洋在晚白垩世末期(68Ma左右)的构造演化一直饱受争议。西藏松多地区晚白垩世末期弧岩浆岩包括花岗斑岩和二长花岗岩。锆石定年结果显示,二长花岗岩和花岗斑岩年龄均为68Ma。松多花岗斑岩和二长花岗岩的Si O_2含量为68.5%~80.6%,K_2O含量为4.1%~6.5%,P2O5含量为0.011%~0.058%。花岗斑岩Mg#值较低,为11.3~19.0,二长花岗岩Mg~#值为24.2~43.5。花岗斑岩和二长花岗岩样品均显示轻稀土元素富集、重稀土元素亏损和明显的Eu(δEu=0.15~1.21)负异常。两者均富集大离子亲石元素Rb、Th、U、K、Pb等,亏损高场强元素Nb、Ta、Ti。花岗斑岩εHf(t)值为-0.9~+2.9,二阶段模式年龄T_(DM)~C在955~1196Ma之间;二长花岗岩εHf(t)值为-17.1~+7.9(只有1个点为负值),二阶段模式年龄在633~2219Ma之间。最终认为,松多地区晚白垩世末期二长花岗岩和花岗斑岩岩浆源区为新生下地壳,但花岗斑岩更靠近古老下地壳。结合区域资料,认为新特提斯洋在晚白垩世末期68Ma左右属于洋脊俯冲结束阶段。     

Ridge subduction,magmatism, and metallogenesis

Modern oceans contain large bathymetric highs(spreading oceanic ridges, aseismic ridges or oceanic plateaus and inactive arc ridges) that, in total, constitute more than 20–30% of the total area of the world's ocean floor. These bathymetric highs may be subducted, and such processes are commonly referred to as ridge subduction. Such ridge subduction events are not only very common and important geodynamic processes in modern oceanic plate tectonics, they also play an important role in the generation of arc magmatism, material recycling, the growth and evolution of continental crust, the deformation and modification of the overlying plates, and metallogenesis at convergent plate boundaries. Therefore, these events have attracted widespread attention. The perpendicular or high-angle subduction of mid-ocean spreading ridges is commonly characterized by the occurrence of a slab window, and the formation of a distinctive adakite–high-Mg andesite–Nb-enriched basalt-oceanic island basalt(OIB) or a mid-oceanic ridge basalt(MORB)-type rock suite, and is closely associated with Au mineralization. Aseismic ridges or oceanic plateaus are traditionally considered to be difficult to subduct, to typically collide with arcs or continents or to induce flat subduction(low angle of less than 10°) due to the thickness of their underlying normal oceanic crust(6–7 km) and high topography. However, the subduction of aseismic ridges and oceanic plateaus occurred on both the western and eastern sides of the Pacific Ocean during the Cenozoic. On the eastern side of the Pacific Ocean, aseismic ridges or oceanic plateaus are being subducted flatly or at low angles beneath South and Central American continents, which may cause a magmatic gap. But slab melting can occur and adakites, or an adakite–high-Mg andesite–adakitic andesite–Nb-enriched basalt suite may be formed during the slab rollback or tearing. Cu-Au mineralization is commonly associated with such flat subduction events. On the western side of the Pacific Ocean, however, aseismic ridges and oceanic plateaus are subducted at relatively high angles(30°).These subduction processes can generate large scale eruptions of basalts, basaltic andesites and andesites, which may be derived from fractional crystallization of magmas originating from the subduction zone fluid-metasomatized mantle wedge. In addition,some inactive arc ridges are subducted beneath Southwest Japan, and these subduction processes are commonly associated with the production of basalts, high-Mg andesites and adakites and Au mineralization. Besides magmatism and Cu-Au mineralization,ridge subduction may also trigger subduction erosion in subduction zones. Future frontiers of research will include characterizing the spatial and temporal patterns of ridge subduction events, clarifying the associated geodynamic mechanisms, quantifying subduction zone material recycling, establishing the associated deep crustal and mantle events that generate or influence magmatism and Cu-Au mineralization, establishing criteria to recognize pre-Cenozoic ridge subduction, the onset of modernstyle plate tectonics and the growth mechanisms for Archean continental crust.     

藏北羌塘中部上二叠统—下三叠统天泉山组的建立及意义——对龙木错-双湖-澜沧江洋构造演化的指示

藏北羌塘中部改则县以北天泉山、屏风岭等地区大面积分布一套浅变质岩系,岩性以变质杂砂岩、千枚岩为主,夹变质玄武岩、变质安山岩等火山岩夹层,因缺乏化石依据时代不明。通过LA-ICP-MS锆石U-Pb同位素定年测得安山岩的~(206)Pb/~(238)U年龄为251.4±2.4Ma,同时结合该地区已测得的254Ma的~(206)Pb/~(238)U年龄,证实这套浅变质岩系的时代应属于晚二叠世—早三叠世,并非传统意义的展金组。在剖面测制和区域对比的基础上,将天泉山、屏风岭一带的浅变质岩系重新厘定为上二叠统—下三叠统天泉山组。天泉山组的发现和建立不仅进一步完善了该区的地层系统,而且是龙木错-双湖-澜沧江洋首次发现的晚二叠世—早三叠世洋盆地层记录,为进一步丰富和研究龙木错-双湖-澜沧江洋的演化提供了重要的地层证据。     

藏南松多地区板多铅锌矿床流体包裹体特征及矿床成因

藏南松多地区板多铅锌矿床位于冈底斯成矿带东段,矿床产于松多岩组、花岗闪长岩与隐伏似斑状花岗岩的接触带及其附近,迄今共圈定3个矿体,矿体呈脉状、透镜状,受北东向断裂控制。矿石中主要金属矿物为方铅矿、闪锌矿与黄铜矿,其次为毒砂、黄铁矿、磁黄铁矿等;非金属矿物以石英、绢云母为主,其次为白云母与方解石。矿床可划分为3个成矿阶段:Ⅰ.石英-毒砂-黄铁矿-磁黄铁矿阶段;Ⅱ.石英-黄铁矿-闪锌矿-黄铜矿-方铅矿阶段;Ⅲ.石英-方解石阶段。其中,第Ⅱ阶段为主成矿阶段。为查明成矿物理化学条件和成矿流体特征,选取主要成矿阶段的石英开展流体包裹体岩相学和显微测温研究。结果表明,石英主要发育气液两相包裹体,并含有少量纯液相与纯气相包裹体;成矿流体属中温、低盐度、低密度的Na Cl-H2O体系;成矿早期存在沸腾现象,之后,流体的减压降温应是铅锌富集成矿的主要因素。综合成矿地质条件、矿床地质特征及流体包裹体研究,初步认为,板多铅锌矿属中温热液脉型铅锌矿床。     

青藏高原羌南-保山板块都古尔地区早白垩世变质辉长岩:对班公湖-怒江洋俯冲闭合的制约

班公湖-怒江洋的俯冲闭合过程对于青藏高原早期形成与演化研究具有重要的意义。在羌南-保山板块腹地都古尔地区识别出早白垩世变质辉长岩。对其进行了详细的岩石学、年代学和全岩地球化学研究。锆石U-Pb测年结果显示,该辉长岩形成年龄为110.4±1.4Ma。全岩地球化学特征显示,该辉长岩具有碱性玄武岩的特征,富集轻稀土元素,轻、重稀土元素分馏较强,无明显的Eu异常;富集Rb、Pb、Nd和Ti,亏损Ba、K、Sr和Y,具有洋岛型玄武岩的亲缘性。该辉长岩为尖晶石-石榴子石二辉橄榄岩经低程度部分熔融的产物,源区存在少量的石榴子石残留。岩浆在上升过程中经历了少量下地壳物质的混染和以斜方辉石为主的分离结晶作用。在综合区域最新研究成果的基础上,认为该辉长岩形成于板内环境,为班公湖-怒江洋闭合后洋脊俯冲的产物。