南秦岭耀岭河群裂谷型火山岩锆石U—Pb年代学

南秦岭耀岭河群以变质基性火山岩为主,夹少量酸性火山岩和碎屑岩。基性火山岩和凝灰岩的TIMS法锆石U-Pb同位素年龄分别为808Ma±6Ma和746Ma±2Ma,表明耀岭河群主体形成于南华纪,西峡-淅川一带所谓的“武当岩群”明显年轻于中元古代武当岩群,应该属于耀岭河群。耀岭河群大陆裂谷型火山岩是全球Rodinia超大陆在新元古代晚期南华纪裂解过程中的产物,反映秦岭造山带和Rodinia超大陆的形成演化密切相关。     

碧口群火山岩岩石成因研究

新元古代(846~776Ma)碧口群火山岩喷发于大陆板内裂谷环境。该火山岩系以基性火山岩为主,酸性火山岩次之,中性火山岩少见。根据岩石地球化学数据,碧口群裂谷基性熔岩总体上属于低Ti/Y(<500)岩浆类型。元素和同位素数据表明,碧口群基性熔岩的化学变化不是由一个共同的母岩浆的结晶分异作用所产生。它们极有可能是源于地幔柱源(εNd(t)≈+3,87Sr/86Sr(t)≈0.704,La/Nb≈0.7)。地壳混染作用对于碧口群裂谷基性熔岩的形成有重要贡献。我们的研究揭示,碧口群火山岩存在空间上的岩石地球化学变化。东部红岩沟和辛田坝—黑木林地区的碧口群基性熔岩以拉斑玄武岩为主,产生于幔源石榴子石稳定区的高度部分熔融。相反,西部白杨—碧口地区的碧口群基性熔岩的母岩浆则是形成于幔源的尖晶石-石榴子石过渡带:碱性熔岩是产生于部分熔融程度较低的条件下,拉斑玄武质熔岩则是产生于部分熔融条件较高的条件下。它们经受了浅层位辉长岩质(cpx+plag±ol)分离作用,化学变异较大。     

南秦岭中段西乡群火山岩岩石成因

南秦岭中段新元古代中期（730-845Ma）西乡群（自下而上包括孙家河组、大石沟组和白勉峡组）火山岩喷发于大陆板内裂谷环境。它们极有可能与导致Rodinia超大陆裂谷化裂解的地幔柱活动有关。根据岩石地球化学数据．南秦岭中段新元古代中期西乡群裂谷基性熔岩总体上属于低Ti／Y（LT,Ti／Y〈500）岩浆类型。LT熔岩又可进一步划分为LT1和LT2等2个亚类。LT1熔岩以高Nb／La（0．87～0．98）、低Thw／NbN（≈1）、缺乏Nb—Ta和Ti的亏损、具有“大隆起”式微量元素原始地幔标准化分配型式、（^87SrSr^86Sr）（t）=0．703869、εNd（t）=4．83为特征,属于拉斑玄武质岩浆系列;LT2熔岩以低Nb／La（〈0．75）、高ThN／NbN（〉1．4）、Nb—Ta和Ti亏损明显和Sr—Nd同位索比值变化较大为特征。元素和同位素数据表明,西乡群裂谷火山岩的化学变化不是由一个共同的母岩浆结晶分异作用所产生。孙家河组、大石沟组和自勉峡组中TiO2含量大于1．09％的火山岩的母岩浆经受了辉长岩质结晶分离作用。而白勉峡组中TiO2含量小于0．69％的基性熔岩的化学演化则是受控于单斜辉石（cpx）±橄榄石（ol）结晶分离作用。西乡群火山岩系中,基性、中性和酸性熔岩间为分异结晶关系。南秦岭中段新元古代中期西乡群裂谷火山岩系极有可能是源于共同的地幔柱,该地幔柱组分的成分为;εNd（t）≈＋5,^87Sr／^86Sr（t）≈0．704,La／Nb≈0．7。南秦岭中段新元古代中期西乡群裂谷基性熔岩存在空间上的地球化学变化：LT1熔岩的母岩浆,没有受到明显的大陆岩石圈混染,保存了鲜明的地幔柱信号;而大陆地壳或大陆岩石圈混染作用对于LT2熔岩的形成则有着重要贡献。研究揭示,南秦岭中段新元古代中期西乡群裂谷基性熔岩的母岩浆总体上产生于上涌地幔柱上部层位（地幔柱头）3GPa?     

武当地区新元古代岩浆岩地球化学特征及其对南秦岭晋宁期区域构造性质的指示

对南秦岭武当地区武当群火山岩、基性侵入岩墙群和耀岭河群火山岩系统的元素和Nd同位素地球研究化学研究表明，武当群火山岩为形成于约1．0－0．9Ga的新元古代陆缘岛弧火山岩，而耀岭河群火山岩与武当地区基性侵入岩墙群为0．82－0．78Ga形成的大陆裂谷型同源岩浆岩；分别可与扬子克拉通北缘西乡群和南秦岭陕西境内的镇安磨沟峡火山岩、扬子克拉通北缘的火地垭群铁船山组碱性火山岩和望江山基性侵入岩群相对比，揭示出南秦岭与扬子克拉通北缘于晋宁期属统一的陆块。扬子克拉北缘和南秦岭大量的新元古代岩浆岩所具有的1．2－0．9GaNd同位素模式年龄和较高的εNd正值特征表明，晋宁期是扬子克拉通地壳增生和大陆岩石圈演化的重要时期之一。     

华南新元古代中期裂谷火山岩系：Rodinia超大陆裂谷化-裂解的地质纪录

华南新元古代中期（746-827Ma）双峰式（玄武岩-流纹岩）火山岩喷发于大陆板内裂谷环境。它们极有可能与导致Rodinia超大陆裂谷化-裂解的地幔柱（或超级地幔柱）活动有关。根据岩石地球化学数据,华南新元古代中期裂谷基性熔岩可以划分为高Ti／Y（HT,Ti／Y〉500）和低Ti／Y（LT,Ti／Y〈500）两个岩浆类型。HT熔岩又可进一步划分为HT1和HT2等两个亚类。HT1熔岩主要分部于华南中-西部裂谷盆地之中,总体上属于碱性玄武质岩浆系列;HT2和LT熔岩主要分布于华南中-东部裂谷盆地之中,总体上属于拉斑玄武质岩浆系列。元素和同位素数据表明,华南新元古代中期裂谷基性熔岩的化学变化不是由一个共同的母岩浆结晶分异作用所产生。华南中-西部地区裂谷基性熔岩的母岩浆经受了辉长岩质结晶分离作用,而华南中-东部地区裂谷基性熔岩的化学演化则是受控于单斜辉石（cpx）士橄榄石（01）结晶分离作用。各个双峰式火山岩系中,基性和酸性熔岩间为分异结晶关系。华南新元古代中期裂谷火山岩系极有可能是源于共同的地幔柱,该地幔柱组分的成分为：eNd（f）≈＋6,Mg#≈0．7,La／Nb≈0．7。华南新元古代中期裂谷基性熔岩存在空间上的地球化学变化：华南中一西部HT1熔岩的母岩浆,没有受到明显的大陆岩石圈混染,保存了鲜明的地幔柱信号;而大陆地壳或大陆岩石圈混染作用对于华南中-东部LT和HT2熔岩的形成则有着重要贡献。研究揭示,华南新元古代中期裂谷基性熔岩的母岩浆总体上产生于上涌地幔柱较深层位的石榴子石稳定区（深度：100～130km）。中-西部裂谷基性熔岩的母岩浆（碱性玄武质）产生于深度较大（～130km）、部分熔融程度较低（〈10％）的条件下,中-东部裂谷基性熔岩的母岩浆（拉斑玄武质）产生于深度稍浅（～100km）?     

武当地块基性岩墙群及耀岭河群基性火山岩的Sr、Nd、Pb、O同位素研究

武当地块基性岩墙群与耀岭河群基性火山岩的 Ｓｒ、 Ｎｄ、 Ｐｂ 同位素特征反映它们具相同的混合地幔源区。前者的（８７ Ｓｒ／８６ Ｓｒ）ｉ＝ ０６９０５～０７０６１, ε Ｎ ｄ （ｔ） ＝ － １９～５０, Δ２０８ Ｐｂ／２０４ Ｐｂ＝ ３５４９～１９０２６, Δ２０７ Ｐｂ／２０４ Ｐｂ＝ ４～８５, Ｔｈ／ Ｔａ 低, Ｌａ／ Ｙｂ 变化大;后者的（８７ Ｓｒ／８６ Ｓｒ）ｉ＝ ０６４８７～０７０７５,ε Ｎ ｄ（ｔ）＝ ０１１～３９４, Δ２０８ Ｐｂ／２０４ Ｐｂ＝ － ８１５８～２１９９５, Δ２０７ Ｐｂ／２０４ Ｐｂ＝ ４４４～１６６８, Ｔｈ／ Ｔａ 和 Ｌａ／ Ｙｂ 较高。这指示它们的源区以岩石圈亏损地幔和第２ 类富集地幔为主要混合组分, 耀岭河群基性火山岩曾遭受地壳物质的混染。结合它们具大陆拉斑玄武岩地球化学特征, 代表同源异相裂谷环境的产物推断, 南秦岭基底陆块在新元古代时曾发生过一次重要裂解作用, 并向早古生代秦岭洋盆转变。     

武当地块基性侵入岩群的地质特征与构造意义

南秦岭构造带武当地块中发育密集侵位的基性侵入岩群，由于武当地区构造变形复杂，这些基性侵入岩体的侵位特征一直没有明确的研究结果。而查明它们的侵位特征，对认识其侵位机制、判断岩浆侵位的大地构造背景以及开展进一步的岩石地球化学和岩浆动力学的研究都具有重要意义。本文通过在武当地块不同构造部位所做的一些详细的1：5万地质填图以及相应的构造学研究表明，这些侵入岩体是顺层侵位到武当山岩群和耀岭河组中的，少数直接侵位到震旦系陡山沱组和邓影组中，侵入体密集发育的部位受武当地块古生代顺层伸展拆离构造的主拆离面控制。作者同时获得了402Ma的单颗粒锆石U—Pb年龄，表明这些基性侵入岩群形成于中古生代。因此无论这些基性侵入岩群的地质特征，还是其同位素年代学测试结果，都表明与前人所说的元古代超大陆的裂解很可能没有直接的成因联系。考虑到这个时期南秦岭构造带中发生的紫阳-岚皋碱性岩浆活动、镇安-旬阳浅层塌陷盆地、武当地块伸展滑脱构造及随枣地区基性侵入岩群的侵位等地质构造事件，作者认为武当地块基性侵入岩群很可能是古生代时期南秦岭岩石圈拉伸所导致的深部基性岩浆上侵的结果。     

南秦岭鄂西北竹山地区早白垩世岩浆岩的发现及地质意义

<正>武当地块南接扬子板块北缘,西南与北大巴山加里东褶皱带相邻,是卷入南秦岭构造带中的前震旦纪浅变质过渡基底地块。该区域地层主要为新元古界武当山群和耀岭河群、震旦系陡山沱组和灯影组以及古生代地层。区内中酸性岩浆岩相对贫乏,但广泛发育基性岩脉。目前对武当地块岩浆岩的年代学研究报道的几乎均为新元古代或古生代年龄,这与东、西秦岭及大别-苏鲁造山带记录的大量中生代年龄数据截然不同。例如,周鼎武等[1-2]获得武当地块中基性岩墙年龄为782±164 Ma(Sm-Nd等时线)和694±21 Ma(角闪石40Ar/39Ar);胡建民等[3-4]则认为这些所谓基性岩墙实     

南秦岭地区存在两种不同构造属性的耀岭河群

广泛分布于南秦岭构造带的耀岭河群变质火山岩对南秦岭构造带的属性，乃至整个秦岭造山带的演化起着十分重要的作用。通过对湖北两郧、陕西商南、镇安和安康凤凰山等地区耀岭河群变质岩石组合、原岩组合、岩石化学和稀土、微量元素等方面的研究表明，在不同地区耀岭河群具有不同的岩石组合、岩石化学和地球化学特征，安康-武当地区中部的耀岭河群为板内拉斑玄武岩-偏碱性玄武岩组合，形成于板内拉张-裂谷环境，而商南耀岭河、镇安和安康凤凰山等地区的耀岭河群则为钙碱性玄武岩-岛弧拉斑玄武岩组合，形成于会聚板块边缘-岛弧构造背景，进一步证实南秦岭地区在6．5～8亿年期间存在两种不同的构造体制。     

南秦岭武当山群变质酸性火山岩锆石U-Pb年代学

对武当山群3个变质酸性火山岩样品的锆石U-Pb定年结果表明,武当山群变质酸性火山岩形成年龄为675.2±3.1 Ma,说明武当山群存在新元古代南华纪的地层组成.武当山群变质变形复杂,具多期岩浆活动,可能由不同时代火山岩和少量沉积岩组成,部分变质火山岩具有与耀岭河群火山岩和侵入到武当山群中的基性侵入岩相似的形成年龄,指示了武当山群变质酸性火山岩可能与基性侵入岩群和耀岭河群火山岩存在成因联系.基于现有同位素定年数据,武当山群火山岩数据具有年龄跨度大(太古宙至中生代)的显著特征,但总的趋势是新近取得的年龄数据多数比早期获得的数据要年轻.     

宿松群、红安群、海州群的时代归属与讨论

系统介绍了分布于大别山—苏鲁造山带南部的原红安群、原宿松群、原肥东群、原海州群的最新研究进展,在将其分别解体为变形变质侵入体及含磷变质火山沉积岩系的基础上,对有关地层时代及其中磷矿层位归属提出了新的论证。     

冀东双山子群及朱杖子群时代归属

双山子群和朱杖子群为一套变余组构保存较好的低角闪岩相－高绿片岩相变质岩系，分布于河北省青龙县双山子一带，东西宽１４ｋｍ，南北长４０ｋｍ。过去大多数地质学家认为，在晚太古代末期－早元古代初期，双山子地区出现裂谷式下陷带，控制了双山子群和朱杖子群的沉积，东部的安子岭杂岩区和西部的迁西群分布区是古隆起区，笔者认为双山子群和朱杖子群是晚太古代生成的，因为，双山子群和朱杖子群与安子岭杂岩和界岭口闪长岩是侵入接触关系，两岩体的Ｒｂ－Ｓｒ全岩等时年龄分别为２４５２Ｍａ和２４４６Ｍａ。在双山子东南２８ｋｍ的庙沟也出露面积约２ｋｍ２的朱杖子群，在安子岭杂岩和界岭口闪长岩中见有大量两群表壳岩的包体，作为朱杖子群底砾岩的老爷庙砾岩，砾石成分主要是闪长岩、火山岩和粉砂岩，从未见到片麻岩。说明砾石来源于下伏双山子群而不是安子岭片麻岩和迁西群片麻岩，因此，晚太古代末期－早元古代初期，双山子一带不是断陷盆地，安子岭地区不是隆起区，双山子群和朱杖子群是晚太古代沉积的。     

On the age of the Onverwacht Group,Swaziland Sequence,South Africa

Some rocks of the Onverwacht Group, South Africa, have been analyzed for Rb and Sr concentrations and Sr isotopie composition. These rocks include volcanic rocks, layered ultramafic differentiates and cherty sediments. Whole rock data indicate that the Rb-Sr isotopie systems in many samples were open and yield no reasonable isochron relationships. However, the data of mineral separates from a basaltic komatiite define a good isochron of $\text{t = 3.50 ± 0.20}$ (2δ) b.y. with an initial Sr⁸⁷/Sr⁸⁶ ratio of $\text{0.70048 ± 5}$(2δ). The orthodox interpretation of this age is the time of the low grade metamorphism. Since the basaltic komatiite is stratigraphically lower than the Middle Marker Horizon (dated as $\text{3.36 ± 0.07}$ b.y. Hurley et al., 1972), and since it is commonly found that volcanism, sedimentary deposition, metamorphism and igneous intrusion in many Archean greenstone-granite terrain all took place in a relatively short time interval (less than 100 m.y.), it is reasonable to assume that the age of 3.50 b.y. might also represent the time of initial Onverwacht volcanism and deposition. The initial Sr⁸⁷/Sr⁸⁶ ratio obtained above is important to an understanding of the Sr isotopic composition of the Archean upper mantle. If the komatiite represents a large degree of partial melt (40–80 per cent) of the Archean upper mantle material, then the initial ratio obtained from the metamorphic komatiite should define an upper limit for the Sr isotopic composition of the upper mantle under the African crustal segment.     

Petroloy of the Taga Volcano Group,Izu Peninsula,Central Japan

The Taga Volcano Group of the Izu Peninsula is divided into four volcanoes: Older Taga, Atami, Shimo-Taga and Himenosawa. Each volcano consists of basalt-andesite lavas and volcaniclastic sediments, mainly of low alkali tholeiite composition.The activity of the Shimo-Taga Volcano is divided into three stages (early, middle and later). Rocks of the first two stages consist of lavas and volcaniclastic sediments of olivine basalt, phyric and aphyric basaltic andesite. The later stage rocks consist of volcaniclastic sediments which were erupted as mudflow deposits.Basalts and andesites of the first two stages are considered to have been derived from a zoned magma chamber. They were produced by fractional crystallization, which involved the gravitational separation of plagioclase, olivine and/or pyroxene crystals. Eruption of aphyric and phyric basaltic andesite from the upper part of the chamber occurred first, followed by olivine basalt from lower parts of the chamber.

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Zusammenfassung Die Taga-Vulkan Gruppe besteht aus dem älteren Taga, dem Atami, dem Shimo-Taga und dem Himenosawa Vulkan. Jeder dieser Vulkane wird aus basaltisch-andesitischen Laven und vulkano-klastischen Sedimenten, hauptsächlich subalkalisch tholeiitischer Zusammensetzung, aufgebaut.Die Eruptionstätigkeit des Shimo-Taga Vulkans läßt sich in drei Phasen, eine Früh-, Mittel- und Spätphase untergliedern. Laven und vulkanoklastische Sedimente der ersten beiden Phasen bestehen aus Olivinbasalten, sowie aus basaltischen Andesiten mit porphyrischem und nichtporphyrischem Gefüge. Während des letzten Stadiums wurden vulkanoklastische Sedimente in Form von vulkanoklastischen Schlammströmen eruptiert.Die Basalte und Andesite der ersten beiden Stadien werden als Produkte einer zonierten Magmenkammer gedeutet. Sie entstanden durch fraktionierte Kristallisation und durch die gravitative Abtrennung von Plagioklas, Olivin und/oder Pyroxenkristallen. Der Eruption der porphyrischen und nichtporphyrischen basaltischen Andesite aus dem obersten Teil der Magmakammer folgte die Eruption von Olivinbasalten aus dem tieferen Teil der Magmakammer.

     

Geochemistry of the Archean Bulawayan Group,Midlands greenstone belt,Rhodesia

The Bulawayan Group in the Midlands greenstone belt can be divided into three formations. The Mafic Formation is composed principally of pillowed, low-K tholeiites and minor bedded chert. The Maliyami Formation and conformably overlying Felsic Formation are composed of calc-alkaline tholeiites, andesites, and dacites with andesites dominating in the Felsic Formation. Minor rhyolite quartz porphyries and ultramafic bodies also occur in the section. The Bulawayan Group near Que Que is perhaps the least altered and metamorphosed Archean greenstone succession known. The absence of andesite and related rocks, the association of bedded chert, and the consistently low K₂O, Rb, and Sr contents of Mafic Formation tholeiites suggest that they represent Archean oceanic rise tholeiites. The compositions of tholeiites and andesites of the Maliyami Formation, however, suggest that they represent an emerging arc system. The Felsic Formation is interpreted as a more advanced stage in the evolution of this arc system.Trace-element model calculations favor an origin for Mafic Formation tholeiites involving about 30% partial melting of a lherzolite source. Similar calculations are consistent with an origin for Maliyami Formation tholeiites, Maliyami and Felsic Formation andesites, and Midlands rhyolites involving, respectively, 50, 20–30, and 10% equilibrium melting of eclogite or garnet amphibolite (of Mafic Formation tholeiite composition). The low K₂O, Rb, and Sr contents of Mafic Formation tholeiites suggest that they were derived from an upper mantle source as depleted in these elements as the oceanic upper mantle is today.A plate tectonic model is proposed for the Bulawayan Group in which the Mafic Formation is derived from a depleted lherzolite source beneath a spreading center in a marginalsea basin and the Maliyami and Felsic Formations and associated rhyolites are produced by partial melting of eclogite in a descending slab located west of the basin.     

创建国际型工程公司开展工程总承包和项目管理方面的经验

中国寰球工程公司的前身为成立于1953年的化工设计公司，是新中国组建的第一个全国性化工设计单位。51年来，寰球走在行业改革的前列，由小到大，由事业单位到科技型企业，由设计院到国际型工程公司，由国内市场到国内外多元市场，坚持不懈地走创建国际型工程公司、发展工程总承包和项目管理承包之路。成为一个智力、技术密集，     

Radiostratigraphic study of the deposits of the Maikop Group, Western Azerbaijan

This work presents the results of biostratigraphic study of natural outcrops of the Maikop Group, which were first carried together with detailed radiometric studies in the Ganja oil and gas-bearing region, Western Azerbaijan. The paleontological research method included determination of the genus or species (depending on the preservation) of microfaunistic remains (foraminifera, ostracods, fish remains). The radiometric research method included measurements of the integral radioactivity in the field, the sampling, as well as laboratory radionuclide (spectral) analysis. As a result of our research, the stratigraphic control of variation in the radioactivity of rocks of the Maikop Group of the Ganja oil and gas-bearing region has been established. The radioactivity of Oligocene rocks is predominantly determined by potassium content. The radioactivity of the Miocene part of the section of the Maikop Group is determined by uranium-potassium contents. Within the Ganja oil and gas-bearing region, deposits of the Kotsakhurian regional stage, which are usually referred to ??barren?? formations or anoxic ??fish facies??, contain a significant number of species of benthic foraminiferal fauna.     

Radiolarian-bearing conglomerate from the Hayang Group, the Kyongsang Supergroup, southeastern Korea

The non-marine Cretaceous Kyongsang Supergroup, which is divided into the Sindong, the Hayang and the Yuchon groups, is widely distributed in southeastern Korea. Radiolarian-bearing pebbles are collected from the conglomerates of the Kumidong and the Kisadong formations of the Hayang Group. The age of radiolarian fossils range from Late Permian to Middle Jurassic. In Korea, Permian to Middle Jurassic marine chert beds are not exposed. The directions of paleocurrents of the Kumidong and the Kisadong formations are mainly from the northeast to southwest. During Cretaceous time, the Mino-Tamba Belt, within which Permian to Middle Jurassic chert beds are exposed, is suggested to have been located northeast of the Kyongsang Basin. The radiolarian faunas of the Hayang Group are similar to those of the Mino-Tamba Belt and other associated Mesozoic accretionary belts in Japan (e.g. the Ashio Belt). The provenance of the radiolarian-bearing pebbles collected from the Kumidong and the Kisadong formations is interpreted to be the Mino-Tamba Belt and other associated Mesozoic accretionary belts in Japan.