EMI型皖东上第三系大陆碱性玄武岩：Nd,Sr同位素证据

本文报导皖东地区上第三系大陆碱性玄武岩的地球化学特征和成因初探，其中８个样品的Ｎｄ、Ｓｒ同位素组成范围为．在大洋玄武岩的Ｎｄ－Ｓｒ同位素平面上，表现为从原始地幔向ＥＭＩ型地幔端元展布趋势．皖东玄武岩具有轻稀土和高度不相容性元素相对富集的微量元素丰度模式，类似于洋岛玄武岩（ＯＩＢ）．皖东玄武岩的源区可能是Ｎｄ、Ｓｒ同位素组成不均一、且富化的大陆岩石圈地幔．     

吕梁山区五台群顶部地层的Sm-Nd年龄——兼论岩浆源区地幔的特殊性

本文根据Sm-Nd同位素工作结果,给出五台群的顶界年龄为2470Ma,属太古代地层。华北地台基底的太古代地层中几处出现世界上同时代的其它构造单元中尚未发现过的高∈~Nd(T)值,表明当时地幔的局部不均匀性已很可观。岩石的既往亏损史与Nd相对富集的情况相矛盾,可能是由于深部地幔去气流体的补入或形成时间不长的地壳物质的混染。     

非均质各向异性对地层渗流及油井产能的影响

非均质和各向异性对油藏内渗流及油井产能有明显影响。假设各向异性地层被间断面分隔成具有不同渗透率的非均质区域,利用坐标变换和镜像原理得到非均质各向异性地层渗流流动的解析解,给出了渗流特征和油藏工程分析。通过分析得出：一般情况下各向异性地层中的井点与其镜像井相对于间断面呈非对称分布,等压线在各区域内部呈椭圆形分布,但在间断面附近呈不规则分布。当相邻区域渗透率小于井所在区域渗透率时,各向异性强度越大,间断面与渗透率最大主方向夹角越大,则井控制面积越小,产量越小;反之亦然。当间断面与渗透率最大主方向夹角较大时,应适当加大井位到间断面的距离,以便增加单井的控制面积和产量;当间断面与渗透率最大主方向夹角较小时,应适当缩小井位到间断面的距离,以便提高间断面附近地质储量动用程度和最终采收率。     

可积函数的原函数的存在性问题

研究了可积函数的原函数存在性问题,讨论了函数可积性与存在性的相互关系.     

金属离子对皱纹盘鲍组织培养的影响

采用3因素3水平L9（3^4）的正交设计，以组织块增殖百分率作为评价指标，研究了在M199和RPMI-1640培养基中分别添加Ca^2＋，Mg^2＋，Zn^2＋金属离子对鲍的外套膜和上足触手组织培养的影响．结果显示，Ca^2＋和Zn^2＋对细胞增殖具有明显的促进作用，Mg^2＋的作用不明显；对上足触手细胞生长最好的组合为5g／L的Ca^2＋，1g／L的Mg^2＋，20μg/L的Zn^2＋；对外套膜细胞生长最好的组合为1g／L的Ca^2＋，1g／L的Mg^2＋，60μg／L的Zn^2＋．     

岩石层底部切向应力场及地球大地水准面异常

比较了两种不同方法,即Runcorn 方程和地幔对流模型,计算了作用于岩石层底部的切向应力场.讨论了在三种不同的边界模型下,核-幔边界对于地球大地水准面的贡献.结果表明:模型Ⅰ(自由核-幔边界;摩擦岩石层-地幔边界)和模型Ⅲ(刚性核-幔边界,摩擦岩石层-地幔边界)中,核幔边界对于地球大地水准面的贡献随球谐函数系数的增加而减少,在n≥2时可以忽略下边界的影响.而模型Ⅱ(摩擦核-幔边界,自由表面)中下边界影响不容忽视.证明使用Runcorn 方程计算岩石层底部的切向应力场是一个合理的近似.     

Peridotite-melt interaction: A key point for the destruction of cratonic lithospheric mantle

This paper presents an overview of recent studies dealing with different ages of mantle peridotitic xenoliths and xenocrysts from the North China Craton, with aim to provide new ideas for further study on the destruction of the North China Craton. Re-Os isotopic studies suggest that the lithospheric mantle of the North China Craton is of Archean age prior to its thinning. The key reason why such a low density and highly refractory Archean lithospheric mantle would be thinned is changes in composition, thermal regime, and physical properties of the lithospheric mantle due to interaction of peridotites with melts of different origins. Inward subduction of circum craton plates and collision with the North China Craton provided not only the driving force for the destruction of the craton, but also continuous melts derived from partial melting of subducted continental or oceanic crustal materials that resulted in the compositional change of the lithospheric mantle. Regional thermal anomaly at ca. 120 Ma led to the melting of highly modified lithospheric mantle. At the same time or subsequently lithospheric extension and asthenospheric upwelling further reinforced the melting and thinning of the lithospheric mantle. Therefore, the destruction and thinning of the North China Craton is a combined result of per- idotite-melt interaction （addition of volatile）, enhanced regional thermal anomaly （temperature increase） and lithospheric extension （decompression）. Such a complex geological process finally produced a ＂mixed＂ lithospheric mantle of highly chemical heterogeneity during the Mesozoic and Cenozoic. It also resulted in significant difference in the composition of mantle peridotitic xenoliths between different regions and times.     

Some basic concepts and problems on the petrogenesis of intra-plate ocean island basalts

Basaltic magmatism that builds intra-plate ocean islands is often considered to be genetically associated with ＂hotspots＂ or ＂mantle plumes＂. While there have been many discussions on why ocean island basalts （OIB） are geochemically highly enriched as an integral part of the mantle plume hypothesis, our current understanding on the origin of OIB source material remains unsatisfactory, and some prevailing ideas need revision. One of the most popular views states that OIB source material is recycled oceanic crust （ROC）. Among many problems with the ROC model, the ocean crust is simply too depleted （e.g., [La/Sm]PM 〈1） to be source material for highly enriched （e.g., [La/Sm]pM 〉〉 1） OIB, Another popular view states that the enriched component of OIB comes from recycled continental crust （RCC, i.e.; terrigenous sediments）. While both CC and OIB are enriched in many incompatible elements （e.g., both have [La/Sm]PM 〉〉1）, the CC has characteristic enrichment in Pb and deletion in Nb, Ta, P and Ti. Such signature is too strong to be eliminated such that CC is unsuitable as source material for OIB. Plate tectonics and mantle circulation permit the presence of ROC and RCC materials in mantle source regions of basalts, but they must be volumetrically insignificant in contributing to basalt magmatism. The observation that OIB are not only enriched in incompatible elements, but also enriched in the progressively more incompatible elements indicates that the enriched component of OIB is of magmatic origin and most likely associated with low-degree melt metasomatism. H2O and CO2 rich incipient melt may form in the seismic low velocity zone （LVZ）. This melt will rise because of buoyancy and concentrate into a melt rich layer atop the LVZ to metasomatize the growing lithosphere, forming the metasomatic vein lithologies. Erupted OIB melts may have three components： （1） fertile OIB source material from depth that is dominant, （2） the melt layer, and （3） assimilation of the metasomatic vein lithologies formed earlier in the growing/grown lithosphere. It is probable that the fertile source material from depth may be （or contain） recycled ancient metasomatized deep portions of oceanic lithosphere. In any attempt to explain the origin of mantle isotopic end-members as revealed from global OIB data, we must （1） remember our original assumptions that the primitive mantle （PM） soon after the core separation was compositionally uniform/homogeneous with the core playing a limited or no role in causing mantle isotopic heterogeneity; （2） not use OIB isotopes to conclude about the nature and compositions of ultimate source materials without understanding geochemical consequences of subduction zone metamorphism; and （3） ensure that models and hypotheses are consistent with the basic petrology and major/trace element geochemistry.     

Carboniferous adakites and Nb-enriched arc basaltic rocks association in the Alataw Mountains, north Xinjiang： interactions between slab melt and mantle peridotite and implications for crustal growth

Adakites and Nb-enriched arc basaltic rocks (NEABs) in arc setting, which are closely correlated in petrogenesis, have recently been widely followed with interest[1—9]. In general, adakite is derived from partial melting of subducting oceanic crust[1]. When adakitic magma (slab melt) passes through the mantle wedge, the interactions between slab melt and mantle peridotite will occur: slab melt is contaminated by peridotite, meanwhile peridotite is metasomated by slab melt. The NEABs are d…     

Origin of ore-forming fluids of the Dachang Sn-polymetallic ore deposit: Evidence from helium isotopes

The ore genesis model for the Dachang Sn- polymetallic ore deposit has long been in dispute, and the major debate focuses on whether the stratiform and massive orebodies formed during the Yanshanian magmatic-hydro- thermal event or they were products of Devonian syn-sedimentary exhalative-hydrothermal event. This note presents new helium isotope data from fluid inclusions of four pyrites and one fluorite. The pyrites were collected from the stratiform and massive orebodies in the deposit, and their 3He/4He ratios are significantly higher than 1, ranging from 1.7 to 2.5 Ra, which indicates a mantle component in the responsible hydrothermal fluids. It is suggested that the ore-forming fluids were a mixture of deep circulating seawater and a mantle-derived fluid, which are similar to many of those modern submarine hydrothermal fluids. In contrast, the fluorite, collected from a granite-related hydrothermal vein in the deposit, shows a low 3He/4He ratio of 0.7 Ra, which indicates no mantle component involvement in the fluids. Hence, the helium isotope data indicate that the two kinds of fluids from the Dachang deposit may have different origins. Together with other geological and geochemical evidence, it is suggested that the stratiform and massive ore formation has no genetic relation to the Yanshanian granite. Rather, they were likely formed during Devonian submarine exhalative-hydrothermal processes.