青川鹰咀山花岗岩体侵位与山脉隆升

运用磷灰石裂变径迹法对鹰咀山花岗岩进行了分析,所取样品的裂变径迹年龄位于50.6⁶9.6Ma之间,小于其地层时代或侵入年龄,表明摩天岭推覆构造带的隆升开始于晚白垩世,用磷灰石裂变径迹年龄来计算可知:研究区内花岗岩50.6Ma以来的冷却速率和剥蚀速率分别为2.08℃/Ma和0.063mm/a,50.669.6Ma之间,小于其地层时代或侵入年龄,表明摩天岭推覆构造带的隆升开始于晚白垩世,用磷灰石裂变径迹年龄来计算可知:研究区内花岗岩50.6Ma以来的冷却速率和剥蚀速率分别为2.08℃/Ma和0.063mm/a,50.6⁶9.6Ma之间的相对抬升与剥蚀速率为0.013mm/a,因此说明摩天岭推覆构造带从晚白垩世以来一直处于持续隆升冷却的过程。     

黔中隆起金沙地区中新生代隆升剥蚀的裂变径迹分析

对贵州金沙地区取样进行了裂变径迹热史模拟,结合地质分析再现了黔中隆起的沉降和隆升剥蚀作用过程。该地区经历了180～70Ma时期的沉降埋藏增温和70Ma之后的剥蚀冷却降温两大阶段。沉降阶段的增温速率为0.909℃/Ma,对应的T3—K的沉积厚度约为4550m。冷却降温曲线分为三段:70～15Ma,样品温度从120℃降低到60℃,冷却速率为1.09℃/Ma;15～5Ma为一个"平台"期,样品温度维持在60℃左右;5Ma至今,样品温度从60℃快速冷却至20℃,冷却速率达8℃/Ma,这与喜马拉雅期云贵高原的整体隆升和晚期快速崛起相对应。计算表明,晚白垩世以来的隆升剥蚀量达2800m左右。     

喜马拉雅造山带晚新生代构造隆升的裂变径迹证据

喜马拉雅造山带的隆升,在地质学研究中是一个非常让人感兴趣的问题,为了对其进行定量研究,揭示隆升历史及幅度等相关问题,运用磷灰石、锆石裂变径迹法对研究区淡色花岗岩进行了分析,所取样品的裂变径迹年龄位于17.0~5.7 Ma之间,小于其地层时代或侵入年龄(40~17 Ma),表明研究区喜马拉雅造山带的强烈隆升开始于晚新生代.用磷灰石裂变径迹年龄来计算可知,研究区内花岗岩5.7 Ma以来的冷却速率和剥蚀速率分别为18.421 ℃/Ma和0.526 mm/a.5.7~9.2 Ma间的相对抬升与剥蚀速率为0.229 mm/a,9.2~17.0 Ma间的相对抬升与剥蚀速率为0.032 mm/a.用锆石裂变径迹年龄来计算知,研究区内花岗岩16.2 Ma以来的冷却速率和剥蚀速率分别为12.963 ℃/Ma和0.370 mm/a,冷却速率和剥蚀速率均小于用磷灰石计算的结果.因此说喜马拉雅造山带从9.2 Ma到现在隆升和剥蚀的速率是处于加快的状态.      

青川鹰咀山花岗岩体侵位与山脉隆升

运用磷灰石裂变径迹法对鹰咀山花岗岩进行了分析,所取样品的裂变径迹年龄位于50.6~69.6Ma之间,小于其地层时代或侵入年龄,表明摩天岭推覆构造带的隆升开始于晚白垩世,用磷灰石裂变径迹年龄来计算可知:研究区内花岗岩50.6Ma以来的冷却速率和剥蚀速率分别为2.08℃/Ma和0.063mm/a,50.6~69.6Ma之间的相对抬升与剥蚀速率为0.013mm/a,因此说明摩天岭推覆构造带从晚白垩世以来一直处于持续隆升冷却的过程。     

云南中甸地区晚白垩世斑岩型Mo-Cu矿床磷灰石、锆石裂变径迹年代学研究

云南中甸地区位于西南三江铜钼铅锌金多金属矿集区的南端,是一个独具特色的Cu-Mo多金属复合叠加成矿带.本文采用裂变径迹低温热年代学技术对区内晚白垩世铜厂沟、休瓦促、热林成矿斑岩体,进行了锆石、磷灰石裂变径迹分析测试,开展了晚白垩世以来的构造热史演化模拟,揭示了区内构造-岩浆成矿事件及热史演化过程.研究表明,锆石裂变径迹年龄值变化于52±2～96±5 Ma;磷灰石裂变径迹的年龄值变化于15±1～48±3 Ma,总体变化幅度不大,中心年龄与池年龄在误差范围也基本一致.通过锆石、磷灰石的裂变径迹分析,揭示出云南中甸地区自晚白垩世以来主要经历了三个阶段的构造热事件.第一阶段(96～60 Ma),主要为岩浆侵位后快速降温的热史演化阶段;第二阶段(52～39 Ma),为缓慢的降温作用过程;第三阶段(16～15 Ma),揭示了受中新世以来青藏高原隆升造山作用的影响,该区经历了快速降温的地质演化过程.综合锆石裂变径迹、磷灰石裂变径迹的热史反演结果,表明区内晚白垩世典型成矿斑岩体具有相似的隆升过程和剥蚀历史,并获得了剥蚀量与剥蚀速率的定量计算结果,为区内矿床的资源潜力评价及勘查工作提供了科学参考.     

藏北改则康托盆地逆冲推覆构造磷灰石裂变径迹年代学制约

对采自羌塘地块南部改则地区康托盆地的碎屑岩及火山岩进行磷灰石裂变径迹年代学测试及AFT热历史模拟,获得77±6Ma、62±5Ma、44±3Ma、35±2Ma四组磷灰石裂变径迹年龄,平均径迹长度介于11.6±2.0~13.3±1.9μm之间。AFT热历史模拟结果指示,研究区自晚白垩世至现今主要历经了3次构造抬升冷却过程:晚白垩世(100~65Ma)快速隆升剥蚀阶段,其降温速率和隆升速率分别为1.46~4.26℃/Ma、0.05~0.14mm/a,该事件为新特提斯洋洋壳沿雅鲁藏布江俯冲作用的响应;始新世中期(50~35Ma)快速隆升剥蚀阶段,该阶段降温幅度相对以第一次较小,该构造事件与印度大陆的向北俯冲具有成因联系;20Ma至现今的快速抬升冷却阶段为青藏高原整体拉张走滑构造环境所影响,其隆升速率和降温速率分别为3.25~6.0℃/Ma、0.03~0.2mm/a。     

黄陵隆起中-新生代隆升作用的裂变径迹证据

通过对8个样品磷灰石裂变径迹年龄和3个样品锆石裂变径迹年龄的测定以及时间-温度热演化历史的反演,研究黄陵隆起中新生代的隆升作用过程,结果表明：黄陵隆起自晚三叠世200Ma开始隆升,表现为持续的隆升过程,经历了4个阶段：200Ma～160Ma±的缓慢隆升冷却作用阶段;160Ma～98．4Ma的快速隆升冷却阶段,岩体进入磷灰石部分退火带中;之后进入了一个构造相对稳定的阶段,样品滞留在部分退火带中;随后36．7Ma～28．4Ma以来,再次快速隆升剥蚀冷却。两次快速的隆升作用指示了中扬子地区两次强烈的构造活动和构造变革。作为印支期以来持续的古隆起,黄陵隆起周缘地区是中扬子地区海相油气运聚有利的指向区。     

MESOZOIC AND CENOZOIC UPLIFT-DENUDATION ALONG THE ALTYN TAGH FAULT,NORTHWESTERN CHINA: CONSTRAINTS FROM APATITE FISSION TRACK DATA

本文利用裂变径迹方法探讨阿尔金断裂中段吐拉-肃北之间隆升和剥露过程.古生代花岗岩和侏罗系沉积岩的磷灰石裂变径迹年龄介于107.2 ±9.0Ma到14.1±1.3Ma之间,明显小于其侵位年龄或者沉积年龄.自西部的吐拉到东端的肃北,磷灰石裂变径迹年龄逐渐升高,从14.1±1.3Ma增加到107.2±9.0Ma.花岗岩和侏罗系砂岩的磷灰石裂变径迹模拟结果表明,阿尔金断裂南侧地质体经历了两阶段的快速冷却过程,早期为33Ma左右,晚期为8Ma左右;阿尔金断裂北侧经历了晚白垩世开始的相对缓慢的冷却过程以及8Ma以来快速冷却事件.阿尔金断裂南北两侧的地质体的裂变径迹年龄和热历史略有差异,可能反映阿尔金断裂的影响.33Ma左右的快速冷却事件可能是阿尔金断裂活动引起的快速去顶作用的开始,这一事件对应了印度和欧亚板块碰撞.8Ma左右的冷却事件,与阿尔金山地区盆地内的快速沉积过程相一致,同时可能是青藏高原抬升与侧向生长在本区的响应.     

青藏高原东部雀儿山地区新近纪隆升速率探讨——来自雀儿山花岗岩体磷灰石裂变径迹证据

通过青藏高原东部川西地区雀儿山花岗岩体磷灰石裂变径迹分析,新获得了4个磷灰石裂变径迹年龄值,分别为4. 9±0. 3Ma、6. 2±0. 5 Ma、7. 2±0. 4 Ma和7. 3±0. 7 Ma。运用径迹年龄-地形高差法计算出雀儿山花岗岩体新近纪的隆升速率,为0. 15～2 mm/a,平均隆升速率为0. 78mm/a。隆升速率在每个阶段有所不同,但呈现出一种快速隆升→缓慢隆升的过程,为整个青藏高原东缘的隆升过程提供了约束条件。     

西昆仑卡日巴生岩体和苦子干岩体的隆升：来自磷灰石裂变径迹分析的证据

笔者对采自青藏高原西北部塔什库尔干县城西侧卡日巴生花岗岩体和苦子干碱性花岗岩体的7个不同高程的样品进行了磷灰石裂变径迹年龄和径迹长度的测试分析。结果表明,自5Ma以来,这一地区经历了脉动式的,总体由缓慢到快速的隆升过程。通过“径迹年龄—高程”法等计算的隆升速率表明,5～2Ma隆升速率为0.1mm/a±;2Ma后,隆升速率增至2mm/a±。同时对样品进行了径迹长度的分析,表明5Ma以来的隆升并不是一个持续抬升过程,存在着相对稳定的阶段,总体表现为一脉动式隆升。并结合区域地质资料分析,认为早期的隆升与印度板块与欧亚大陆的碰撞挤压有关,2Ma后的隆升是由青藏高原内部热均衡调整造成的。所测试的样品中,6个样品的磷灰石裂变径迹年龄在2.14～5.19Ma,显示出随着样品高程的增加,裂变径迹年龄增大的规律。而其中一个样品的单颗粒径迹年龄较为分散,揭示了早期与隆升有关的热历史的信息。     

摩擦桩基桩土间极限摩阻力取值问题探讨

通过对广珠东线高速公路横沥大桥的试桩及土体的工程地质条件分析,总结出影响摩擦桩基桩土间极限摩阻力取值的一般问题以及解决问题的方法和措施。     

从榴辉岩与围岩的关系论苏鲁榴辉岩的形成与折返

位于华北和扬子两板块碰撞带中的苏鲁榴辉岩形成的温压条件不但是超高压，而且是高温。榴辉岩的PTt轨迹表明其为陆-陆磁撞俯冲带的产物。榴辉岩的区域性围岩花岗质片麻岩为新元古代同碰撞期花岗岩，榴辉岩及其他直接围岩皆呈包体存在于其中，并见新元古代花岗岩呈脉状侵入榴辉岩包体中。区域性围岩新元古代花岗岩的锆石中发现有柯石英、绿辉石等包裹体，表明新元古代花岗岩的组成物质也经受过超高压变质作用，且榴辉岩与围岩新元古代花岗岩的锆石U-Pb体系同位素年龄基本相同。但新元古代花岗岩所记录的变质作用和变形作用期次（或阶段）却少于榴辉岩。椐上述可得如下推断：超高压榴辉岩与新元古代花岗岩岩浆是同时在碰撞带底部（俯冲板块前部）形成的；榴辉岩的第一折返阶段是由新元古代花岗岩岩浆携带上升的，其第二折返阶段是和新元古代花岗岩一起由逆冲及区域性隆起而上升，遭受剥蚀。     

The Importance of the Precipitation and the Susceptibility of the Slopes for the Triggering of Landslides Along the Roads

In order to characterise the influence of the heavyrains on the observed landslides during the 1996–1997hydrological cycle, rainfall records for the last 100years are analysed from 104 stations in easternAndalusia. Regarding the amounts of rain recordedbetween October 1996 and March 1997 in the 104stations studied, 31 presented new all-time records;15 presented values that were 80–100% of thepre-1995 record; 49 stations, 80–50%; and 9stations, < 50%. A map has been devised of thesusceptibility of the materials through which thesouth-eastern Andalusian road network crosses,together with an inventory of the damage caused byinstability phenomena on banks and cuttings of theroad network during the winter of 1996–1997. Therelationships between the rainfall during the studyperiod, the damage caused to the road network and thesusceptibility of the materials affected are analysed.The results indicate that there is a clearcorrespondence between the rainfall recorded and thesusceptibility of the materials with the inventorieddamage. It is concluded that the widespread seriousdamage caused in early 1997 to the roads andsurrounding areas in the Alpujarra region and thecoast of the Province of Granada was mainly caused bythe extraordinarily heavy rains. However, considerablyless damage was observed where the susceptibility ofthe terrain is low, thus highlighting the extremeusefulness of terrain-susceptibility maps for riskprevention and territorial planning.     

某高速公路下伏煤矿采空区稳定性分析

在论述某高速公路下伏砦脖煤矿采空区地质、采矿和工程地质特征的基础上, 进行了稳定性数值模拟分析, 定性与定量地分析与评价了该煤矿采空区的地表变形特征及稳定性。研究结果表明: 该煤矿采空区的变形尚未完成, 对拟建的高速公路将产生很大的危害, 必须采取相应的工程治理措施。      

混凝剂处理钻井废泥浆液的研究

通过烧杯搅拌实验对混凝剂处理钻井废泥浆液进行研究,从混凝剂适应p H值范围、混凝效果、沉降速度三方面研究比较,找出一种较为理想的混凝剂,并分析了影响混凝剂性能的主要因素,确定了混凝剂的最佳投放剂量。      

黄河源区水环境变化及黄河出现冬季断流的原因

自1954年有水文观测资料以来，黄河曾在青海省玛多县黄河沿水文站发生过3次断流。本文在分析黄河源区水环境特征及其影响因素的基础上指出，鄂陵湖、扎陵湖的环湖融区调节能力低，当遇到连续干旱、冬季其调节水量不足以维系黄河径流时便会发生断流，这是断流的主因。湖水位降低、开采沙金、过度放牧等自然和人为因素也会对黄河发生断流产生影响。鄂陵湖口附近黄河上修建的水电站开始蓄水，提高了两湖及环湖融区的调节能力，今后黄河冬季出现断流的可能性将大为降低。     

Unity of the national and the international in the socio-cultural development of the peoples of the USSR

International unity is becoming ever stronger in this country owing to an increasing similarity in the development of the cultural environment. This comprises the provision of all the country's republics with a sufficient number of schools, theatres, and other institutions and cultural information media in accordance with the needs of the population. An important part is played by the rise in ‘the general educational level, as well as the level of professional qualifications and skills. Among all the Soviet nations and nationalities, this rise being more rapid among formerly backward peoples. Prominent among the factors of internationalization is the progressive development of the nationalities’ cultural resources, while professional culture is being increasingly brought within the reach of the masses.The implementation of the nationalities policy promotes the all-round development of all Soviet nations and nationalities, their drawing together, the upsurge of the individual capabilities of every Soviet citizen.     

Artemia in the Salt Lakes of Russia:the Productivity of Populations,the Reserves of the Cysts and the Fisheries

正Artemia cysts are an extremely important component of aquaculture diets.It is well established that the cultivation of fish and shellfish derive substantial health and growth advantages when Artemia are included in the diets of the     

天山南坡科其喀尔冰川表碛区小气候特征研究

利用天山南坡科其喀尔冰川3号观测站2009年全年的气象观测资料,分析研究了科其喀尔冰川表碛区的小气候特征. 结果表明：总辐射和净辐射夏秋季较高、冬春季较低;反射辐射和地表反照率反之. 与其他地区不同,该区主要受积雪物理性质和下垫面状况的影响,冬春季地表反照率日变化表现为由大到小的变化过程,夏秋季表现为倒U型. 温度年变化表现为夏秋季高、冬春季低,最高月均值出现在8月,为9.4℃,最低月均值出现在1月,为-9.6℃. 受山谷风和冰川风的影响,全年的风向以西北风和西北偏西风为主,风向的日变化以11：00为界发生转向. 受降水和冰川消融等的影响,比湿夏秋季月均值较大,冬春季月均值较小.     

Climate: Is the past the key to the future?

 The climate of the Holocene is not well suited to be the baseline for the climate of the planet. It is an interglacial, a state typical of only 10% of the past few million years. It is a time of relative sea-level stability after a rapid 130-m rise from the lowstand during the last glacial maximum. Physical geologic processes are operating at unusual rates and much of the geochemical system is not in a steady state. During most of the Phanerozoic there have been no continental ice sheets on the earth, and the planet’s meridional temperature gradient has been much less than it is presently. Major factors influencing climate are insolation, greenhouse gases, paleogeography, and vegetation; the first two are discussed in this paper. Changes in the earth’s orbital parameters affect the amount of radiation received from the sun at different latitudes over the course of the year. During the last climate cycle, the waxing and waning of the northern hemisphere continental ice sheets closely followed the changes in summer insolation at the latitude of the northern hemisphere polar circle. The overall intensity of insolation in the northern hemisphere is governed by the precession of the earth’s axis of rotation, and the precession and ellipticity of the earth’s orbit. At the polar circle a meridional minimum of summer insolation becomes alternately more and less pronounced as the obliquity of the earth’s axis of rotation changes. Feedback processes amplify the insolation signal. Greenhouse gases (H₂O, CO₂, CH₄, CFCs) modulate the insolation-driven climate. The atmospheric content of CO₂ during the last glacial maximum was approximately 30% less than during the present interglacial. A variety of possible causes for this change have been postulated. The present burning of fossil fuels, deforestation, and cement manufacture since the beginning of the industrial revolution have added CO₂ to the atmosphere when its content due to glacial-interglacial variation was already at a maximum. Anthropogenic activity has increased the CO₂ content of the atmosphere to 130% of its previous Holocene level, probably higher than at any time during the past few million years. During the Late Cretaceous the atmospheric CO₂ content was probably about four times that of the present, the level to which it may rise at the end of the next century. The results of a Campanian (80 Ma) climate simulation suggest that the positive feedback between CO₂ and another important greenhouse gas, H₂O, raised the earth’s temperature to a level where latent heat transport became much more significant than it is presently, and operated efficiently at all latitudes. Atmospheric high- and low-pressure systems were as much the result of variations in the vapor content of the air as of temperature differences. In our present state of knowledge, future climate change is unpredictable because by adding CO₂ to the atmosphere we are forcing the climate toward a “greenhouse” mode when it is accustomed to moving between the glacial–interglacial “icehouse” states that reflect the waxing and waning of ice sheets. At the same time we are replacing freely transpiring C3 plants with water-conserving C4 plants, producing a global vegetation complex that has no past analog. The past climates of the earth cannot be used as a direct guide to what may occur in the future. To understand what may happen in the future we must learn about the first principles of physics and chemistry related to the earth’s system. The fundamental mechanisms of the climate system are best explored in simulations of the earth’s ancient extreme climates. Received: 7 November 1996/Accepted: 23 January 1997