渔塘坝硒矿床多元素富集与沉积环境

对采自湖北西部渔塘坝二叠系独立硒矿区的硅质岩和页岩样品进行了元素测试（微量元素、总铁、总有机碳、总硫）,分析了该区域的多元素富集及沉积环境。该区域V、Cu、As、Cd、Tl、Se、Mo、V、 Sb、 U、Ag、 Cr、Ni相对富集, Ba、Hf、Ta、W、Pb、Th相对贫化或亏损。全硫—全铁（TS—TFe）的关系表明页岩及部分硅质岩的S/Fe比值均大于1.15,说明有过量的硫存在,可能为有机硫或为其他亲硫元素沉淀提供条件。TOC—TS—TFe三角图及V/(V + Ni)表明该区域的岩石形成于缺氧或静海相环境。U/Th、Zr—Cr、P—Y等微量元素地球化学参数表明该区域有热水沉积的存在。通过对微量元素可能的来源研究分析,该区域的微量元素可能存在多种来源:热水来源、海水沉积、峨眉山玄武岩。     

滇西羊拉铜矿床稀土元素地球化学研究

滇西羊拉铜矿是近年来发现的大型铜矿床。本文系统研究了该矿床不同岩石、矿石、矿石矿物及脉石矿物的稀土元素地球化学特征,研究表明：矿区花岗闪长岩具有与壳幔型花岗岩类相似的稀土元素特征;早期形成的块状硫化物矿石及其矿物中稀土元素含量高,富集轻稀土,具有负Ｅｕ异常,与赋矿地层碎屑岩、硅质岩的稀土元素球粒陨石标准化配分相似,反映其成矿物质来源于上地壳;中晚期形成的夕卡岩矿石及破碎带充填、交代型矿石及其矿物中     

鲁西石炭纪事件沉积岩石学特征

对鲁西地区石炭二叠纪煤系火山碎屑岩特征进行了分析,结果表明,火山碎屑物质以晶屑最为常见,常见的火山碎屑岩有凝灰岩、沉凝灰岩、凝灰质灰岩、凝灰质砂岩、凝灰质粉砂岩。还对在太原组煤层中发现的宇宙尘形貌及化学组成进行了研究,经与国内外相关资料对比,认为研究区宇宙尘为Si质玻璃球。提出了研究区石炭纪曾发生过火山地质事件、天体地质事件。      

黔西地区煤层埋深与地应力对其渗透性控制机制

基于黔西六盘水煤田和织纳煤田16口井36层次的试井资料, 采用地质统计分析等方法, 探讨了黔西地区煤储层渗透性的展布规律与地应力特征, 论证了煤层埋深与地应力对其渗透性的控制机制.研究表明, 研究区煤储层以特低渗-低渗透率储层(＜0.1×10-9m2)为主, 中渗透率储层(0.1×10-9~1.0×10-9m2)也占有相当大比例; 应力场类型在浅部表现为大地动力场型, 一定深度可能转化为准静水压力状态.煤储层渗透率及其埋深的负幂指数关系较为离散, 但在不同深度渗透率转折点与地应力场类型转变一致; 单井煤储层试井渗透率差异较大, 随地应力增大和埋深增加而降低, 平面展布受地应力强度控制由SW-NE具"低-高-低"发育规律.埋深对渗透率的控制实质是地应力的控制, 区域构造位置及其所处高应力场作用下的煤体形变与破碎致使孔裂隙压缩或闭合是该区渗透性差异的主要控制机制.      

新疆西准噶尔拉巴西蛇绿混杂岩带地质特征及其意义

新疆西准噶尔地区是古生代经过俯冲-增生形成的复合造山带。该地区分布有多条蛇绿岩带,其中的拉巴西蛇绿岩带是比较重要的一条,通过对该蛇绿混杂岩特征的研究,认为该区蛇绿岩尽管受到强烈的多期构造肢解,但根据岩石类型仍能恢复蛇绿岩的原始层序。本文重点讨论了拉巴西蛇绿混杂岩的地球化学特征,认为其形成时代为晚寒武世-中奥陶世,就位时代为中晚志留世,蛇绿混杂岩产于弧前或弧后小洋盆环境。研究发现,该蛇绿混杂岩具有明显的铬铁矿化,为下一步找矿指明了方向。     

Contrasting hydrography and phytoplankton distribution in the upper layers of cyclonic eddies in the Mozambique Basin and Mozambique Channel

Hydrographic data collected in cyclonic eddies in the Mozambique Channel and Basin revealed notable differences in temperature and salinity at a depth of 100 m, the upper mixed layer, the nitracline depths, and vertical distribution of chlorophyll-a (Chl-a). Differences in temperature and salinity did not show any consistent patterns. In contrast, the differences in the upper mixed layer, nitracline depths and the vertical Chl-a profile appeared to be driven by combined effects of eddy dynamics (i.e. shoaling of isopleths) and the seasonal variation in light availability and mixing conditions in the upper layers. Cyclonic eddies studied during austral spring and summer in the Mozambique Channel exhibited shallower upper mixed layers and nitracline depths, and deeper euphotic zones. Distinct subsurface Chl-a maxima (SCM) were associated with the stratified conditions in the upper layers of these eddies. In contrast, a cyclonic eddy studied during mid-austral winter in the Mozambique Basin had a shallower euphotic zone, deeper upper mixed layer and uniform Chl-a profiles. Another eddy sampled in the Mozambique Basin toward the end of winter showed a less pronounced SCM and roughly equal euphotic zone and upper mixed layer depths, suggestive of a transition from a well-mixed upper layer during winter to stratified conditions in summer.     

Differing controls on river‐ and lake‐water hydrogen and oxygen isotopic values in the western United States

Surface water oxygen and hydrogen isotopic values are commonly used as proxies of precipitation isotopic values to track modern hydrologic processes while proxies of water isotopic values preserved in lake and river sediments are used for paleoclimate and paleoaltimetry studies. Previous work has been able to explain variability in USA river‐water and meteoric‐precipitation oxygen isotope variability with geographic variables. These studies show that in the western United States, river‐water isotopic values are depleted relative to precipitation values. In comparison, the controls on lake‐water isotopic values are not well constrained. It has been documented that western United States lake‐water input values, unlike river water, reflect the monthly weighted mean isotopic value of precipitation. To understand the differing controls on lake‐ and river‐water isotopic values in the western United States, we examine the seasonal distribution of precipitation, evaporation and snowmelt across a range of seasonality regimes. We generate new predictive equations based on easily measured factors for western United States lake‐water, which are able to explain 69–63% of the variability in lake‐water hydrogen and oxygen isotopic values. In addition to the geographic factors that can explain river and precipitation values, lake‐water isotopic values need factors related to local hydrologic and climatic characteristics to explain variability. Study results suggest that the spring snowmelt runs off the landscape via rivers and streams, depleting river and stream‐water isotopic values. By contrast, lakes receive seasonal contributions of precipitation in proportion to the seasonal fraction of total annual precipitation within their watershed. Climate change may alter the ratio of snow to rain fall, affecting water resource partitioning between rivers and lakes and by implication of groundwater. Paleolimnological studies must account for the multiple drivers of water isotopic values; likewise, studies based on the isotopic composition of fossil material need to distinguish between species that are associated with rivers versus lakes. Copyright © 2010 John Wiley & Sons, Ltd.     

西太平洋地区二叠纪海洋生物地理区系的演化

综述了作者近年来分布在西太平洋地区二叠纪５个不同时间带的腕足动物群的多维统计分析成果,分析结果表明,该地区二叠纪海相生物地理分区性受古气候带和古地理两大因素的明显控制,早二叠世早期和晚二叠世晚期,生物地理分区界线明显,易于识别,但“中二叠世”（相当于栖霞期和茅口期）由于南北出现了两个过渡生物省,即北边的中蒙生物省和南边的基墨利生物省（Ｃｉｍｍｅｒｉａｎ）生物区之间的界线变得模糊,中蒙生物省的出现表     

Influence of Current Width Variation on the Annual Mean Transport of the East Sakhalin Current: A Simple Model

Recent observations suggest that the annual mean southward transport of the East Sakhalin Current (ESC) is significantly larger than the annual mean Sverdrup transport. Motivated by this observational result, transport of a western boundary current has been investigated using a simple numerical model with a western slope. This transport is defined as the instantaneous barotropic transport integrated from the western boundary to the offshore point where the barotropic velocity vanishes. The model, forced by seasonally varying wind stress, exhibits an annual mean of the western boundary current transport that is larger than that of the Sverdrup transport, as observed. The southward transport from October to March in the model nearly equals the instantaneous Sverdrup transport, while the southward transport from April to September decreases slowly. Although the Sverdrup transport in July vanishes, the southward transport in summer nearly maintains the annual mean Sverdrup transport, because the barotropic Rossby wave cannot intrude on the western slope. This summer transport causes the larger annual mean. Although there are some uncertainties in the estimation of the Sverdrup transport in the Sea of Okhotsk, the seasonal variation of the southward transport in the model is qualitatively similar to the observations.     

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