柴达木盆地一里坪盐湖富锂卤水特征、储层物性及富水区分析

一里坪盐湖是柴达木盆地中一个典型的富锂卤水矿床,具有重大的经济价值.本文以查明盐湖深部卤水分布为目的,从卤水储层的空间分布特征和储层物性的角度对富水区进行预测,为卤水开发提供依据.研究区位于一里坪成盐盆地沉积中心区域,晚更新世末期以来,以沉积浅湖相的含淤泥和黏土粉砂岩,盐湖相的含粉砂和黏土的石盐岩为特征.在垂向上,由上下两套石盐岩夹中部粉砂岩组成一里坪富锂卤水的储层;平面上,研究区北部主要为浅湖相,往南过渡为盐湖相,石盐岩厚度在东南部最大.对储层厚度、孔隙度和给水度的分析表明,第Ⅱ矿层孔隙型和晶间型卤水优质储层均位于研究区东部,可作为卤水资源勘查开采的重点区域.     

柴达木盆地昆特依盐湖含杂卤石地层高分辨率矿物学研究

柴达木盆地昆特依盐湖杂卤石资源丰富,是开展现代内陆盐湖杂卤石成因机制研究的良好载体.精细刻画沉积特征对阐释沉积矿床成因具有重要作用.本研究以昆特依盐湖大盐滩矿区ZK3608钻孔岩芯14.08-25.48 m段碎屑-杂卤石沉积韵律为研究对象,开展高分辨率矿物学研究,结合石盐流体包裹体化学组成和石盐中微量元素分析,尝试从高分辨率沉积学和矿物学的角度探讨杂卤石的成因.研究结果显示,石盐层产出的杂卤石含量低但分布范围广,为原生矿物;碎屑层中的杂卤石主要为次生矿物.石盐层与碎屑层之间存在一个过渡层位,该层位的杂卤石高度富集且矿物组成复杂,推测是由于原生与准同生杂卤石短时间内先后形成导致的.结合石盐流体包裹体化学组成所代表的古卤水变化特征分析表明,Ca-Cl型深部油田卤水的补给对研究区不同时期杂卤石的形成有重要影响.地球化学特征综合分析指示,石盐层的原生杂卤石由富钾镁的浓缩卤水与Ca-Cl型深部油田卤水混合直接生成;而过渡层位的杂卤石受到气候变化与Ca-Cl型深部油田卤水补给的共同作用.     

新疆库车盆地古近纪—新近纪盐湖成钾与靶区预测

库车前陆盆地位于塔里木盆地北部,属于副特提斯域,古近纪受副特提斯海海水补给,古近纪—新近纪发育巨厚蒸发岩。研究显示,库车盆地始新世和中新世古盐湖卤水已演化至钾盐析出阶段,在地层中广泛发现了原生钾盐矿物,如钾石盐、光卤石、杂卤石等;通过岩芯岩屑地球化学及矿物学分析,基本确定了至少3个富钾层或成钾层位,其中始新统中上部两个和中新统中上部一个,钾离子含量最高达3%,另外,上新统可能存在一个成钾层位。本文在综述此前库车盆地构造、蒸发岩、盐类矿物学、地球化学与盐湖沉积等研究基础上,建立了新的库车盆地古盐湖构造- 沉积演变、成钾模式;提出了4个钾盐成矿区带,即北部克拉苏成矿带、中部秋里塔克成矿带、南部沙雅构造沉降成矿带以及东部阳霞凹地成钾区,这些关键认识为库车盆地的钾盐勘查提供了重要的理论和科学依据。     

中国含铀盐湖分布特征

通过地质调查和水体铀浓度分析,统计了中国内陆地区淡水湖、咸水湖和盐湖平均铀浓度,讨论了油田水、深层卤水和沿海晒盐场卤水铀浓度水平。根据含铀盐湖所处的大地构造位置、形成有利因素和盐湖铀浓度,将中国含铀盐湖划分为5个分区21个亚区。中国含铀盐湖主要分布在柴达木盆地西北部、藏北高原中西部、鄂尔多斯高原北部和二连盆地中部,包括8片含铀盐湖集中分布区。     

罗布泊盐湖区固体钾盐沉积特征、分布及成因探讨

文章对罗布泊盐湖区杂卤石、光卤石、钾盐镁矾等不同类型固体钾盐矿物特征、分布及成因进行了分析总结。杂卤石主要产于罗北凹地内部沉降区,以交代成因类型为主,代表了以硫酸盐型卤水为主体的罗布泊盐湖残余卤水钾镁富集到一定程度与石膏、钙芒硝发生水-盐反应的产物。光卤石沉积主要产于断陷带（近）地表,为深部氯化物型卤水经断裂向上运移至地表、与浅部卤水掺杂经蒸发浓缩而成。钾盐镁矾主要产于南小团地区,其形成可能与凹陷基底反转、罗北凹地高浓度卤水回灌有关。罗布泊盐湖区不同类型的固体钾盐沉积是构造-物源-气候3种成钾要素在特定时间窗下耦合的产物：在干旱气候条件下,构造活动一方面导致盆地地貌分异形成更加封闭的成钾次级凹地,为钾盐沉积提供可容纳空间;另一方面活化断裂为深部流体补给盐湖提供通道,为钾盐沉积提供不同类型的物质来源,改变盐湖卤水化学组成最终形成不同类型钾盐矿物。     

湖相沉积黏土型锂矿主要地质特征及成因

锂是重要的战略性新能源矿产,主要有卤水型、硬岩型和沉积黏土型3种类型。前两者已有大量开采。现阶段具有开发利用前景的沉积黏土型锂矿主要产于湖相盆地中,其产出规模大、层位浅、矿体分布稳定、厚度大、品位高,具有重要的地质意义和潜在的经济价值。现已发现的湖相沉积黏土型锂矿床主要分布在北美洲、欧洲和中国。该类型矿床赋矿沉积岩的沉积特征、锂的赋存状态、成矿物质来源、成矿环境与成矿机理等研究目前还较薄弱。本文主要介绍全球主要湖相沉积黏土型锂矿的地质特征、赋矿矿物特征和成矿规律,并对国内外湖相沉积黏土型锂资源的成矿作用机理进行综合分析。湖相沉积黏土型锂矿床中锂主要赋存于蒙脱石、伊利石等黏土矿物中,个别为独立含锂矿物贾达尔石。锂的主要物质来源及成矿方式有多种,包括喷发至湖盆中的富锂火山岩（特别是火山灰地层）、深部富锂岩浆热液运移至湖相盆地中并与沉积黏土水岩反应形成,或者通过富锂盐湖卤水与围岩黏土岩的相互作用使得锂吸附在黏土矿物中。全球湖相沉积锂成矿作用的差异主要是成矿物源区和沉积环境的差异所致。     

博茨瓦纳马卡迪卡迪盐湖卤水特征及找钾前景分析

马卡迪卡迪盐湖区为一现代干盐湖,盐湖以湖相碎屑沉积为主,在东侧的苏阿干盐湖赋存有高矿化孔隙卤水,通过对盐湖卤水系统的采样分析及综合研究,卤水主要化学组分为Na+和Cl-,其次为CO3^-2、HCO3^-,SO4^-2、K^+,矿化度平均为257.96g/L,卤水水化学类型为碳酸盐型;卤水组分与矿化度呈明显的正相关,表明卤水还未达到饱和阶段;受湖区构造及补给来源的影响,卤水的富集区位于研究区的西北部,同时也是矿化度最高的地区;KCl的含量在0.39%~0.99%之间,平均在0.65%,已超过液体钾盐矿的最低工业品位,分布面积约690km2,具有一定找矿前景。     

内蒙古呼伦贝尔盟现代盐湖地质特征及形成条件分析

呼盟盐湖面积都比较小，盐湖卤水组分较复杂，但其中所沉积的相应的厚层盐类沉积物组分却比较简单，多为不同纯度的芒硝或泡碱层。盐类沉积的组分和盐湖公布地区有关，也受沉积过程中沉积环境的变化所控制。呼盟盐湖主要形成于古河道盆地、砂丘间洼地和丘陵地区的山间洼地，盐类物质来自周缘地区。由于盐类物质溶解度变化规律的不同和沉积环境变化，盐湖演化过程中产生盐类物质沉积分异作用，因此即使在相邻的盐湖和同一盐湖中，也可形成不同的盐类沉积。     

澧县曾家河无水芒硝矿床分布规律

澧县曾家河无水芒硝矿床，矿层呈层状、似层状，分布于中新生代盐湖相沉积盆地─—澧县盆地，属古内陆盐湖相蒸发岩硫酸盐型沉积矿床，自边缘向中部由钙芒硝→无水芒硝→岩盐，组成环带构造。     

我国西北地区盐湖中的铀234U/238U比值示踪研究

内蒙古二连盆地、鄂尔多斯盆地典型含铀碳酸型盐湖水、岩两相234U/238U综合分析表明,碳酸型盐湖铀来源于大气降水和潜水对盐湖盆地周围中生代到现代富铀沉积物的溶滤、浸出,具有快速、近源物质来源特点。盐湖卤水和对应沉积物234U/238U值一般为0.8～1.2,湖卤水和潜卤水（晶间卤水）-岩两相中的铀处于沉积平衡状态。早白垩世～上新世含膏盐地层对比研究证实了富铀岩层234U/238U值随铀含量增大而减小,并趋近于1。室内盐湖水蒸发模拟实验发现残余卤水、沉积物234U/238U具有随蒸发程度增大逐渐减小的变化特征。盐湖现代沉积物物相研究发现铀主要以碳酸铀酰和吸附形式赋存在富含有机物和碎屑成分的含盐粘土沉积中,铀在盐类晶体中含量极少,仅存在于封闭水和结晶水中。卤水和沉积物ARu值是盐湖铀源及铀含量水平的指示标志之一。     

南秦岭下地壳组成及岩石圈的拆离俯冲作用

根据新提供的Pb同位素组成及岩石地球化学研究成果，本文进一步证实了位于北秦岭北界的明港地区发育的早中生代安山玄武质火山角砾岩岩筒所携带的下地壳捕虏体属于南秦岭。所恢复的南秦岭下地壳剖面自下而上为：底侵成因的变辉长岩-基性麻粒岩(其中含有榴辉岩及辉石岩的透镜体)-酸性麻粒岩。秦岭造山带总体的岩石因模型为：南秦岭(扬子块体)向北拆离俯冲，北秦岭地壳向华北仰冲，华北岩石因呈楔状插入秦岭造山带，拆离面约在中、下地壳之间。南秦岭俯冲岩片延伸的范围在平面上有可能达到400km。     

青藏高原综合观测研究站的回顾与展望

中国科学院青藏高原综合观测研究站从１９８８年建站到１９９８年以来,在各个方面均取得了长足的发展,横向生产性项目的开展和完成不仅解决了部队和地方的实际问题,而且缓和了观测研究站在运行过程中所面临的经费严重不足的问题,同时也为我所冻土专业研究人员提供了在生产中实践的机会,在基础理论研究方面,承担了国家攀登计划项目,国家基金项目,中国科学院重点项目和中国科学院冰冻圈专项项目等的研究工作,在多年冻土变化,     

铀钍的地球化学及对地壳演化和生物进化的影响

本文论述了在含挥发份和贫挥发份条件下Ｕ、Ｔｈ的迁移行为及其对地球和行星演化的影响,并阐述了造成地球独特地质演化历史的原因。提出了Ｕ、Ｔｈ在地球中的迁移模式以及该模式对地壳形成、演化的控制作用和对生物发展演化的可能影响。     

Principles of spatial organization and evolution of the biosphere and the noosphere

In his last lifetime essay, “A Few Words about the Noosphere”, Academician V.I. Vernadsky (1944) wrote that all living organisms on the planet, including man, are integral to the biosphere of the Earth, its material and energy structure and cannot be physically independent of it even for a minute. However, the substrate that generates all living beings and is no less tightly bound to the biosphere has always been characterized by a significant geochemical heterogeneity, traced both in the vertical and in the lateral structure of all geospheres.

The present work is devoted to three most important aspects of modern geochemistry and biogeochemistry:

• — evolution of the ecological and geochemical state of the environment under conditions of a virgin (anthropogenically untouched) biosphere;
• — structural features of the geochemical organization of the modern noosphere;
• — specificity of the interaction of living matter with the environment under increasing anthropogenic load.

On the basis of theoretical concepts of biogeochemistry and geochemical ecology, formulated in the works of V.I. Vernadsky, A.P. Vinogradov, A.E. Fersman, B.B. Polynov, A.I. Perel’man, M.A. Glazovskaya, V.V. Kovalsky, E. Odum, B. Commoner, E.I. Kolchinskii and others, the author puts forward a hypothesis that there exist two qualitatively different stages in the evolution of the biosphere.The first stage is recognized as the period of natural evolution of the biosphere during which it evolves successively into a more complex and more biogeochemically specialized object. In the course of the geological time, this constantly results, on the one hand, in an increase in species diversity and the perfection of individual species, and, on the other hand, to directed improvement and a greater differentiation of the geochemical conditions of the environment. At this stage, the evolution of all systems of the biosphere that were controlled by the mechanisms of self-organization and self-regulation resulted in the establishment of a dynamic equilibrium, which was responsible for the cycling of all essential chemical elements and therefore providing ecologically optimal geochemical conditions in all ecological niches and for all species and biocenoses inhabiting the biosphere at any given moment.The beginning of the second stage is related to the appearance of reason and qualitative changes in the biosphere caused by the goal-directed activity of the human mind, as an entirely new geological force that appeared to be able not only to disrupt the functioning of natural mechanisms of self-regulation and selforganization, but also to transform the environment in the intersts of a single biological species, Homo sapiens. A direct consequence of this change was the uncontrolled transformation of the natural environment, during which the primary structure (geochemical background) created in the course of billions of years was eventually superimposed by a qualitatively new layer of anthropogenically-derived chemical elements and compounds, thus building an interference pattern of a new geochemical field with which practically all modern living organisms are now forced to interact.An outstanding feature of the new evolutionary stage of the natural environment, called by Vernadsky the noosphere, is that biogeochemical changes at this stage proceed at a rate which exceeds that required for the living matter to adapt to these changes. The result is the disruption of the existing parameters of the biological cycle, leading to the emergence of a significant number of endemic diseases of geochemical nature.The proposed approach was used to prove the anthropogenic genesis of existing geochemical endemic diseases and explain the mechanisms of their appearance. In addition, this approach allowed us to develop a new methodology for mapping zones of ecological and geochemical risk and noticeably simplify the procedure of monitoring distribution and prevention of all diseases of geochemical nature.     

Wavelets and the Generalization of the Variogram

The experimental variogram computed in the usual way by the method of moments and the Haar wavelet transform are similar in that they filter data and yield informative summaries that may be interpreted. The variogram filters out constant values; wavelets can filter variation at several spatial scales and thereby provide a richer repertoire for analysis and demand no assumptions other than that of finite variance. This paper compares the two functions, identifying that part of the Haar wavelet transform that gives it its advantages. It goes on to show that the generalized variogram of order k=1, 2, and 3 filters linear, quadratic, and cubic polynomials from the data, respectively, which correspond with more complex wavelets in Daubechies's family. The additional filter coefficients of the latter can reveal features of the data that are not evident in its usual form. Three examples in which data recorded at regular intervals on transects are analyzed illustrate the extended form of the variogram. The apparent periodicity of gilgais in Australia seems to be accentuated as filter coefficients are added, but otherwise the analysis provides no new insight. Analysis of hyerpsectral data with a strong linear trend showed that the wavelet-based variograms filtered it out. Adding filter coefficients in the analysis of the topsoil across the Jurassic scarplands of England changed the upper bound of the variogram; it then resembled the within-class variogram computed by the method of moments. To elucidate these results, we simulated several series of data to represent a random process with values fluctuating about a mean, data with long-range linear trend, data with local trend, and data with stepped transitions. The results suggest that the wavelet variogram can filter out the effects of long-range trend, but not local trend, and of transitions from one class to another, as across boundaries.     

Palaeoecology and the origin of the coconut

While botanists, archaeologists, historians and linguists have contributed to the debate on the origin of the coconut pollen analysts have been silent. This article attempts to integrate the results of recent palaeoecological research with findings from the other disciplines.     

共和盆地层状地貌系统与青藏高原隆升及黄河发育

利用卫星遥感影像,结合实地调查和测年结果,对共和盆地层状地貌系统进行了解译、分析。研究表明,共和盆地层状地貌系统由山麓剥蚀面、洪积扇面、盆地面以及黄河阶地面构成,其空间结构、物质组成对发生于早更新世早期的青藏运动C幕和中更新世末期的共和运动反映清晰。青藏运动C幕使青藏高原主夷平面在高原差异性隆升中彻底解体,垂直变形量高达1700m。共和运动使黄河在0.11Ma进入共和盆地,其后黄河平均以3.5mm/a的侵蚀速率下切盆地,同时在盆地边部的山前古冲洪积扇以大致相近的速率被抬升,最终导致高差在2000m左右的层状地貌系统的出现。