生物土壤结皮固沙理论与实践

生物土壤结皮是由土壤微生物、藻类、地衣和苔藓等孢子植物类群与土壤颗粒形成的有机复合体,在全球干旱区地表广泛分布,是干旱地表生物覆被层的主要构建者.生物土壤结皮是荒漠植物群落演替的先锋类群,能够提高荒漠地表的稳定性,固定碳和氮等营养元素,增加土壤肥力,并在保持土壤水分方面发挥重要作用,因此在干旱区受损地表的生态修复方面具...     

采空区的物探勘查方法

采空区给人类生产生活带来危害,采空区的探测已成为重要研究课题.文章介绍了采空区的地球物理特征,对采空区探测的各种物探方法从重、电、震、放、综合物探等方面进行分类和介绍,有以往使用的老方法,也介绍了采空区探测中使用的新方法.     

黄腊石滑坡基岩弯曲松弛带工程地质特性、形成机制及失稳预测

黄腊石滑坡是发育在三叠系中统巴东组砂泥岩夹灰岩构成的逆倾坡上的滑坡群,总方量约1 800×104 m3.滑坡滑带下面存在着大致连续分布的基岩弯曲松弛带.对于该松弛带工程地质特性的认识,将影响防治工程方案的设计及实施.本文通过野外工作、以往工作资料和研究成果的收集整理及再认识,对该滑坡下伏松弛带工程地质特性、形成机制及失稳预测作了一定深度的探讨,认为基岩弯曲松弛带是发生在特定的岩层中,由构造、重力、侵蚀、岩溶、风化、降雨及上部滑坡等因素共同作用的产物,工程地质环境质量较差,受重力及其上滑体滑动等因素影响,后期改造明显.在斜坡长期受重力累积变形、三峡水库运行期江水位变化及库岸再造作用下,将形成牵引式滑动.防治工程应在削方、排水等基础上,重点考虑防止库岸再造和斜坡坡脚部位变形.     

谈地下水数学模型在南干渠灌区中的预测与应用

地下水数学模型是用数学方法表述,经过概化地下水系统,在系统分析地下水补、径、排的基础上,对地下水预测分析的一种有效方法.随着南干渠灌区建成后水量的变化,本文通过选用适宜的数学模型,对灌区地下水资源量进行模拟计算,根据模拟计算结果对灌区地下水升幅进行预测,对灌区生态环境的变化做出评价.     

新疆哈密大南湖地区层间氧化带特征研究

新疆大南湖地区的层间氧化带发育层位为中侏罗统西山窑组第二、三岩性段砂砾岩,以褐黄色为主;层间氧化带具多层性,埋深31～343 m,厚度2～138 m;层间氧化带分为氧化带、氧化-还原过渡带和原生带;铀矿体主产于氧化-还原过渡带中;新构造运动形成的最终构造格架控制了层间氧化带的发育方向和基本形态,不同粒度且非致密结构的砂砾岩和冲积扇相、辫状河相沉积则决定层间氧化带发育的厚度和规模,由南向北流的承压地下水造成区内层间氧化带前锋线呈向北延伸的趋势.     

攀西水系沉积物铂、钯异常及对找寻铂、钯矿的启示

利用攀枝花幅（永仁幅）、会理幅、盐边幅、米易幅、盐源幅和西昌幅共6个1：20万图幅的区域铂、钯地球化学资料,运用了数据滤波处理方法圈定铂族元素异常.讨论了水系沉积物中铂、钯地球化学背景和异常与峨眉山玄武岩、基性-超基性岩等地质体的空间关系,并做了该地区铂族矿产的找矿远景预测.     

放射性物探方法在辽宁团山子地区金矿找矿中的应用

辽宁省兴城市团山子地区位于青龙-葫芦岛近东西向断裂的东段,碱厂岩体南缘,八家子-杨家杖子多金属成矿区的中南部.通过钻探证实,金矿化受近东西向断裂构造控制,矿化类型为碎裂蚀变岩型,具有低品位、大矿量特点,在辽西地区属首次发现.为加强对本区控矿构造特征和金矿化赋存规律的研究,采用了放射性物探方法进行探索,取得了较好的找矿效果.由于该方法简便易行,对于在区域上寻找该类型金矿具有重要意义,值得借鉴和推广.     

川西高原可尔因地区黄土成因研究

川西高原马尔康县境内的可尔因地区黄土分布广泛.黄土主要呈披盖式分布在3~6级阶地上.采用ESR（电子磁旋共振）测年、黄土粒度分析、SEM扫描电镜石英表面形态观察以及区域资料对比,分析了可尔因地区黄土的风成成因,认为应属冰缘黄土.     

Refining accretionary orogen models for the Tasmanides of eastern Australia

The well-known southwest-to-northeast younging of stratigraphy over a present-day cross strike distance of >1500 km in the southern Tasmanides of eastern Australia has been used to argue for models of accretionary orogenesis behind a continually eastwards-rolling paleo-Pacific plate. However, these accretionary models need modification, since the oldest (ca 530 Ma) outcrops of Cambrian supra-subduction zone rocks occur in the outboard New England Orogen, now ～900 km east of the next oldest (520–510 Ma) supra-subduction zone rocks. This is not consistent with simple, continuous easterly rollback. Instead, the southern Tasmanides contain an early history characterised by a westwards-migrating margin between ca 530 and ca 520 Ma, followed by rapid eastwards rollback of the paleo-Pacific plate from 520 to 502 Ma that opened a vast backarc basin ～2000 km across that has never been closed. From the Ordovician through to the end of the Carboniferous, the almost vertical stacking of continental margin arcs (within a hundred kilometres of each other) in the New England Orogen indicates a constant west-dipping plate boundary in a Gondwana reference frame. Although the actual position of the boundary is inferred to have undergone contraction-related advances and extension-related retreats, these movements are estimated to be ～250 km or less. Rollback in the early Permian was never completely reversed, so that late Permian–Triassic to Cretaceous arcs lie farther east, in the very eastern part of eastern Australia, with rifted fragments occurring in the Lord Howe Rise and in New Zealand. The northern Tasmanides are even more anomalous, since they missed out on the middle Cambrian plate boundary retreat seen in the south. As a result, their Cambrian-to-Devonian history is concentrated in a ～300 km wide strip immediately west of Precambrian cratonic Australia and above Precambrian basement. The presence in this narrow region of Ordovician to Carboniferous continental margin arcs and backarc basins also implies a virtually stationary plate boundary in a Gondwana frame of reference. This bipolar character of the Tasmanides suggests the presence of a segmented paleo-Pacific Plate, with major transform faults propagating into the Tasmanides as tear faults that were favourably oriented for the formation of local supra-subduction zone systems and for subsequent intraplate north–south shortening. In this interpretation of the Tasmanides, Lower–Middle Ordovician quartz-rich turbidites accumulated as submarine fan sequences, and do not represent multiple subduction complexes developed above subduction zones lying behind the plate boundary. Indeed, the Tasmanides are characterised by the general absence of material accreted from the paleo-Pacific plate and by the dominance of craton-derived, recycled sedimentary rocks.