我国矽卡岩型铜矿床同位素地质特征及其“三位一体”成矿模式

总结了典型折矽卡岩型铜矿床同位素地质地球化学特征，认为我国矽卡岩型铜矿床成矿岩体（＾８７Ｓｒ／＾８６Ｓｒ）ｉ一般在０．７０６￣０．７１０变化，岩体为幔壳混合源型。矿石铅同位素组成均匀、稳定，特别是铀铅，＾２０６Ｐｂ／＾２０４Ｐｂ＝１７．０７５￣１８．１００，＾２０７Ｐｂ／＾２０４Ｐｂ＝１５．３３７￣１５．６３５，比值变化小，而＾２０８Ｐｂ／＾２０４Ｐｂ比值变化稍大，矿石铅源主要来自成矿岩体。矿石δ     

滇西羊拉铜矿床稳定同位素地球化学研究

滇西羊拉铜矿是近年来发现的大型铜矿床。作者系统地研究了该矿床的Ｓ、Ｐｂ、Ｃ、Ｏ、Ｓｉ同位素组成,研究表明该矿床不同矿石的硫同位素组成变化范围一致,其平均值靠近零值且具有塔式分布特征,表明硫来源于上地幔或岩浆作用;该矿床矿石中方解石的Ｃ、Ｏ同位素组成与矿区大理岩的Ｃ、Ｏ同位素组成明显不同,其δ＾１３Ｃ（ＰＤＢ）为－３．２７‰～－４．８９‰,与土地幔射气及岩浆作用形成的ＣＯ２的碳同位素组成一致,因此矿石中方解石中碳亦来源于土地幔射气或岩浆作用;铜同位素特征表明早期热水沉积形成的块状硫化物矿石铅主要来源于上地壳,而中晚期形成的夕卡岩型矿石及蚀变破碎带型矿石的铅具有土地幔铅的特征。     

横岭关铜矿床地球化学研究

对横岭关铜矿床中稀土元素、同位素和矿物包裹体地球化学研究表明，矿床形成温度为３５０℃±３０℃；压力为３８×１０~５Ｐａ～２４０×１０~５Ｐａ；盐度为３０ｗｔ％～４２ｗｔ％；ｌｏｇｆｏ_２为－３０．４１～－３１．４７；ｌｏｇｆｓ_２为－５．４～－８；ｐＨ值为７．３；ｌｏｇｆｃｏ_２为－２．４９；铜的溶解度（ｌｏｇｍ_（Ｃｕ））为－５．８７～－２．２１。围岩的铅－铅同位素年龄为１７７５×１０~６ａ，矿石的铅－铅同位素年龄为１８４５×１０~６ａ；矿石硫同位素组成，δ~（３４）Ｓ为－８．１‰～３６．９‰，显示出硫同位素为非平衡特征；碳酸盐岩的碳同位素组成，δ~（１３）Ｃ为－７．１‰～－２．６‰，δ~（１３）Ｃ_（∑Ｃ）为－５．３‰；成矿流体的氢氧同位素组成具有变质热卤水的特点，认为该矿床属于变质热卤水成矿。     

塔中古生界油田水的成因和混合的证据

塔中地区奥陶纱、志留系和石炭系油田水的主元素、微量元素、＾８７Ｓｒ／＾８６Ｓｒ、δＤ、δ＾１８Ｏ及全岩的＾８７Ｓｒ／＾８６Ｓｒ测试结果表明,油田水相对于海水蒸发曲线,富Ｓｒ＾２＋、Ｃａ＾２＋、ＣＦ而贫Ｋ＾＋、Ｍｇ＾２＋,系水－岩反应改造的产物。远高于海水的＾８７Ｓｒ／＾８６Ｓｒ值表明油田水具有钾长石等矿物溶解的影响。油田水＾８７Ｓｒ／＾８６Ｓｒ－１／Ｓｒ的关系显示具有两种混合趋势,一种是奥陶系油田     

浙江西裘铜块状硫化物矿床火山-热泉沉积成矿的地质地球化学证据

浙江西裘矿区新元古代火山－热泉活动强烈,矿石Ｃｕ：Ｚｎ：Ｐｂ原子百分比与火山岩和热水沉积硅质岩相似。矿床δ＾３４Ｓ值为－６．５‰～２．８‰,δ＾１８Ｏ值为８．１４‰～２２．３２‰,铅同位素示踪主要为下地壳铅;矿石具较高的Ａｓ、Ｓｂ、Ｂｉ、Ｇａ、Ｚｎ、Ｂａ等含量;具较低的Ａｌ／（Ａｌ＋Ｆｅ＝Ｍｎ）比值,Ｚｎ（Ｐｂ＋Ｚｎ）比值接近１,均表现出火山－热泉沉积成矿地球化学特征。     

（古）盐度研究的一种重要工具——锶同位素

本文详细地阐述了海水－陆表水双元体系中锶同位素的混合原理、混合水体中＾８７Ｓｒ／＾８６Ｓｒ值与盐度的定量关系。利用Ｓｒ同位素不随生物、何尝作用过程发生分馏作用及Ｓｒ与Ｃａ化学性质相似等特征,地层、沉积物中生物壳体和碳酸盐岩＾８７Ｓｒ／＾８６Ｓｒ值可作为沉积水体（古）盐度确定的一种有用工具。文中详细地综述了国内外在这方面的研究进展,并讨论了成岩后生作用对生物壳体和碳酸盐岩＾８７Ｓｒ／＾８６Ｓｒ原始值     

四川盆地南北缘志留系的锶和碳、氧同位素演化及其地质意义

通过对四川盆地北缘广元地区及南缘綦江地区上奥陶统及下志留统地层的８７Ｓｒ／８６Ｓｒ、δ１３Ｃ及δ１８Ｏ的系统测定,取得了沿地层剖面变化的同位素组成规律。研究结果表明,在盆地南缘８７Ｓｒ／８６Ｓｒ值高于地质历史中海水的平均值,其原因是本区为受板块内古陆控制的缓坡环境,大量陆源锶的混入增加了８７Ｓｒ／８６Ｓｒ的值。８７Ｓｒ／８６Ｓｒ值在上奥陶统至下志留统地层交界处、Ｒｈｕｄｄａｎｉａｎ／Ａｅｒｏｎｉａｎ（鲁丹期／艾隆期）交界处具正峰波动,反映了此时海平面的短时下降。但从Ｒｈｕｄｄａｎｉａｎ至Ｔｅｌｙｃｈｉａｎ（特里奇期）,８７Ｓｒ／８６Ｓｒ逐渐降低。从Ａｅｒｏｎｉａｎ至Ｓｈｅｉｎｗｏｏｄｉａｎ（舍因伍德期）早期,盆地南北缘的δ１３Ｃ值处于逐渐上升的过程之中,而δ１８Ｏ则相反。同位素的演化特征说明本区当时为海进时期,海平面不断上升,与全球性海平面变化相吻合。由于受区域构造运动的作用,Ｓｈｅｉｎｗｏｏｄｉａｎ之后的全球持续海进对本区无影响。     

我国矽卡岩型铜矿床同位素地质特征及其“三位一体”成矿模式

总结了典型的砂卡岩型铜矿床同位素地质地球化学特征，认为我国矽卡岩型铜矿床成矿岩体（87Sr／86Sr）；一般在0．706～0．710变化，岩体为幔壳混合源型．矿石铅同位素组成均匀、稳定，特别是铀铅，206Pb／204Pb＝17．075～18.100，207Pb／204Pb＝15．337～15．635，比值变化小，而208Pb／204Pb比值变化稍大，矿石铅源主要来自成矿岩体．矿石δ334S值集中在－3．4～＋5．9％之间，成矿流体早期以岩浆水为主，晚期有大气降水、地层水的加入，一般δD(SMOW)为－32‰～－75‰；δ18O(H2O)为＋4．7‰～＋7．9‰;δ13C（PDB）值集中在－6．8‰～＋1．4‰，表现为岩浆碳与地层碳的混合．     

长坑金银矿床的铅,锶,硫同位素特征与矿化模式

长坑矿床金、银矿石的铅同位素组成具有一定的差异，前者的２０６Ｐｂ／２０４Ｐｂ比值变化大，后者较富２０７Ｐｂ／２０８Ｐｂ。金矿石中的铅为普通铅与放射成因铅混合而成的异常铅，银矿石中的铅则可能为三阶段铅混合的产物，且二者均为壳源。方解石的８７Ｓｒ／８６Ｓｒ比值显示锶来自地壳。金、银矿石硫化物的δ３４Ｓ值分别以分散（平均值为负）和较为集中（平均值为正）为特征，并与铅同位素组成之间存在相关关系。结合金、银的矿化分带现象，提出了铅同位素特征与氧化势不同的流体相互混合的成矿模式。     

滇西红层铜矿区域成矿物质来源

兰坪-思茅盆地红层铜矿床可分为沉积成岩型、沉积-改造型和改造型三类，它们的同位素地球化学特征有诸多相似之处。硫同位素组成值域较宽，负值为主，显示地层生物流源为主的特点。铅同位素组成与中新生代沉积岩类似。δ13C值为-10．76‰～＋0．85‰，δD值为-135．6‰～-53.4％‰，δ18OH2O值为-10.57‰～＋9.77‰。87Sr／86Sr值为0.70829～0.72525。不同类型矿床的同位素组成有一定差异。研究结果表明，区域成矿物质以壳源为主，成矿与中低温热卤水活动有关。     

Définition d'une limite multicritère ; stratigraphie du passage Campanien–Maastrichtien du site géologique de Tercis (Landes,SW France)Definition of a multi-criteria boundary; stratigraphy of the Campanian–Maastrichtian interval of the geological site at Tercis (Landes,SW France)

Lithostratigraphy, physicochemical stratigraphy, biostratigraphy, and geochronology of the 77–70 Ma old series bracketing the Campanian–Maastrichtian boundary have been investigated by 70 experts. For the first time, direct relationships between macro- and microfossils have been established, as well as direct and indirect relationships between chemo-physical and biostratigraphical tools. A combination of criteria for selecting the boundary level, duration estimates, uncertainties on durations and on the location of biohorizons have been considered; new chronostratigraphic units are proposed. The geological site at Tercis is accepted by the Commission on Stratigraphy as the international reference for the stratigraphy of the studied interval. To cite this article: G.S. Odin, C. R. Geoscience 334 (2002) 409–414.     

Late Wuchiapingian (Late Dzhulfian,early Late Permian) limestone olistolites within the Tertiary flysch of Glypia Unit (Mount Parnon,central–eastern Peloponnesus,Greece)

Some olistolites reworked in a Tertiary flysch of Mount Parnon (Peloponnesus, Greece) exhibit a Late Permian assemblage, dominated by Paradunbarula (Shindella) shindensis, Hemigordiopsis cf. luquensis and Colaniella aff. minima. This association corresponds to the Late Wuchiapingian (=Late Dzhulfian), a substage whose algae and foraminifera are generally little known. Contemporaneous limestones crop out in the middle part of the Episkopi Formation in Hydra, but they are rather commonly reworked in Mesozoic and Cainozoic sequences. The palaeobiogeographical affinities shared by the foraminiferal markers of Greece, southeastern Pamir, and southern China, are very strong (up to the specific level), and are congruent with the Pangea B reconstructions. To cite this article: E. Skourtsos et al., C. R. Geoscience 334 (2002) 925–931.     

PALEONTOLOGY

正20141596 Liu Yunhuan(School of Earth Sciences and Resources,Chang’an University,Xi’an 710054,China);Shao Tiequan Early Cambrian Quadrapyrgites Fossils of Xixiang Boita in Southern Shaanxi Province(Journal of Earth Sciences and Environment,ISSN1672-6561,CN61-1423/P,35(3),2013,p.39-43,3 illus.,20 refs.)     

GEOCHEMICAL EXPLORATION

正20141719 Chen Zhijun(State Key Laboratory of Geological Processes and Mineral Resources,China University of Geosciences,Wuhan 430074,China);Chen Jianguo Automated Batch Mapping Solution for Serial Maps:A Case Study of Exploration Geochemistry Maps(Journal of Geology,ISSN1674-3636,CN32-1796/P,37(3),2013,p.456-464,2 illus.,2 tables,10 refs.)     

MICROPALAEONTOLOGY

正20140962 Chen Fenning(Xi’an Institute of Geology and Mineral Resources,Xi’an710054,China);Chen Ruiming Late Miocene-Early Pleistocene Ostracoda Fauna of Gyirong Basin,Southern Tibet(Acta Geologica Sinica,ISSN0001-5717,CN11-1951/P,87(6),2013,p.872-886,6illus.,56refs.)     

PETROLOGY

正1.IGNEOUS PETROLOGY20142008Cai Jinhui(Wuhan Center,China Geological Survey,Wuhan 430205,China);Liu Wei Zircon U-Pb Geochronology and Mineralization Significance of Granodiorites from Fuzichong Pb-Zn Deposit,Guangxi,South China(Geology and Mineral Resources of South China,ISSN1007-3701,CN42-1417/P,29(4),2013,p.271-281,7illus.,     

ENVIRONMENTAL GEOLOGY

正20141205Cheng Weiming(State Key Laboratory of Resources and Environmental Information System,Institute of Geographic Sciences and Natural Resources Research,CAS,Beijing 100101,China);Xia Yao Regional Hazard Assessment of Disaster Environment for Debris Flows:Taking Jundu Mountain,Beijing as an     

PROSPECTING EXPLORATION

正20141266Fan Chaoyan(Guangdong Provincial Key Laboratory of Mineral Resources and Geological Processes,Guangzhou 510275,China);Wang Zhenghai On Error Analysis and Correction Method of Measured Strata Section with Wire Projection Method(Journal of     

OCEANOGRAPHY & MARINE GEOLOGY

正20140582 Fang Xisheng(Key Lab.of Marine Sedimentology and Environmental Geology,First Institute of Oceanography,State Oceanic Administration,Qingdao 266061,China);Shi Xuefa Mineralogy of Surface Sediment in the Eastern Area off the Ryukyu Islands and Its Geological Significance(Marine Geology Quaternary Geology,ISSN0256-1492,CN37     

ENVIRONMENTAL GEOLOGY

正20141810 Bian Yumei(Geological Environmental Monitoring Center of Liaoning Province,Shenyang 110032,China);Zhang Jing Zoning Haicheng,Liaoning Province,by GeoHazard Risk and Geo-Hazard Assessment(Journal of Geological Hazards and Environment Preservation,ISSN1006-4362,CN51-1467/P,24(3),2013,p.5-9,2 illus.,tables,refs.)