青藏高原多年冻土区斜坡类型及典型斜坡稳定性研究

冻土区斜坡稳定性是青藏高原工程建设必须面对和解决的问题之一. 介绍了青藏高原多年冻土区斜坡失稳的主要类型, 包括崩塌型、蠕变型、泥流阶地型、表土植被层蠕滑型及热融滑塌型等. 其中热融滑塌型对于高原环境、尤其是植被及工程的危害最为显著, 该类斜坡的诱发因素一般为工程开挖或工程活动对冻土的热扰动, 斜坡失稳的根本原因在于多年冻土融化后强度的减弱或丧失. 在分析了热融滑塌型滑坡失稳机理的基础上, 提出了滑坡治理的原则与工程措施方案建议.     

青藏工程走廊典型热融灾害现象及其热影响研究

在全球变暖及人类工程活动的影响下,青藏工程走廊内的热融灾害普遍发育。研究走廊内各类热融灾害的发育现状及其对多年冻土的热影响对今后的工程规划和冻土环境保护具有一定的指导意义。本文通过大量的野外调查工作,总结了走廊内热融灾害的类型及其发育现状,并选取3种典型热融灾害进行现场地温监测,分析其对多年冻土的热影响方式和程度。研究结果表明:3种热融灾害对其发育区域及附近的多年冻土都产生了巨大的热影响,热融滑塌和热融沟主要影响浅层的地温状况,而热融湖塘的影响范围更大,其发育甚至会导致湖塘下部形成多年融区。此外,侧向热流计算结果表明,3种热融灾害全年都在向其周边的多年冻土放热,通过对比发现热融湖塘的侧向热侵蚀能力最强,其次是热融沟,侧向热侵蚀最小的是热融滑塌。     

多年冻土区斜坡稳定性研究综述

全球变暖、极端天气频发,引发的地质灾害对自然生态环境和人类生产生活造成了很大的影响。尤其对气候变化较为敏感的高温（年平均地温>-1 °C）和高含冰量多年冻土区,气候变暖以及人类活动导致的冻融地质灾害日益频繁。冻土退化条件下,土体结构和物理力学性质发生改变,黏聚力和抗剪强度降低,造成多年冻土区斜坡发生滑坡、崩塌、泥流等灾害。斜坡失稳加剧了多年冻土区脆弱生态环境的恶化,同时对建（构）筑物安全运营产生威胁。与非冻土区相比,多年冻土区斜坡稳定性研究主要针对高含冰量斜坡段,斜坡失稳模式主要以热融滑塌和活动层滑脱为主。热融滑塌由斜坡段地下冰暴露融化引起,而活动层滑脱产生的原因是冻土融化导致土体孔隙水压力过大,形成的超孔隙水压力降低了土体强度,造成斜坡失稳。此外,多年冻土区斜坡失稳模式还包括融冻泥流、崩塌以及蠕变滑坡等。通过综述近期多年冻土区斜坡稳定性研究进展,概括了多年冻土区斜坡失稳的模式、特征、影响因素、失稳机理、分析方法及防治措施等,并对未来多年冻土区斜坡失稳的研究重点提出建议。     

青藏高原多年冻土区两类低角度滑坡灾害形成机理探讨

青藏高原多年冻土区发育的两类低角度滑坡--融冻泥流和热融滑塌是冻融循环条件下特殊的斜坡失稳类型,在广大的非冻土地区一般很难见到这种低角度的滑坡类型。探讨了两类低角度滑坡灾害的形成机理,即质点迁移效应和滞水润滑效应。以摩尔-库仑强度准则为理论基础,应用所推导的沿坡面平行方向渗流条件下安全系数的统一形式,对青藏公路k3035里程热融滑塌体稳定性进行了分析评价,验证了活动层沿厚层地下冰面滑动的“滞水润滑效应”。从环境工程地质学的观点出发,针对热融滑塌这种可控的滑坡地质灾害,提出了基于保护冻土原则的具体的防治措施。     

青藏高原多年冻土区热融滑塌变形现场监测分析

为了了解青藏高原多年冻土区K3035里程热融滑塌体的变形特征,分别在未滑动土体、近滑塌前缘滑体中布设了2个变形监测孔,利用Geokon-603型测斜仪实施了近1 a的变形监测。结果表明,发育在平缓斜坡上的热融滑塌具有明显的变形特征,其位移主要发生在土层浅部,越往深部,位移越小,这一监测结果通过室内数值模拟得到了验证。将阳坡的K3035热融滑塌与阴坡的K3057热融滑塌体的变形做了对比监测,无论是滑塌体后缘还是前缘,前者的滑动变形均显著大于后者。而无热融滑塌发育的斜坡(青藏铁路DK1139)土体变形量极小,这种差异一方面说明了开挖是导致热融滑塌发生的直接因素,另一方面,由于热融滑塌的影响,其后缘相对稳定的原斜坡土体也处于相对较大的蠕变变形之中。     

青藏高原多年冻土热融灾害发展预测

青藏高原多年冻土区是世界上中低纬度多年冻土面积最大的区域,气候变化引起青藏高原多年冻土区年平均地温上升、地下冰融化、多年冻土退化等问题。借助ARCGIS技术手段,通过地下冰计算模型和Stefan公式计算研究区不同气候变化情景模式下的地下冰体积含冰量和活动层厚度变化。结果表明:在未来几十年内多年冻土的分布范围将不会发生显著变化,多年冻土的主要退化形式为地下冰的消融、低温冻土向高温冻土转化;但本世纪末多年冻土将发生大范围的退化。这一过程将引起热融滑塌、热融沉陷等冻土热融灾害。将Nelson热融灾害风险性评价模式进行修正,对研究区灾害风险性进行评估区划。最大的危险区主要分布在西昆仑山南麓、青南山原中部、冈底斯山和念青唐古拉山南麓、喜马拉雅山南麓部分区域,在未来几十年内有加剧的趋势。     

青藏铁路北麓河地区典型热融湖变化特征及其对冻土热状况的影响

在全球气候变暖、青藏高原平均气温升高的大背景下,多年冻土区热融湖的发育及其对冻土热状况的影响日益显著.以北麓河地区的一典型热融湖为例,通过对湖岸坍塌及年地温变化等进行监测分析.结果表明:目前该热融湖湖岸逐年坍塌,坍塌主要发生在靠近铁路一侧厚层地下冰发育区域,年平均坍塌宽度大约为0.5m,湖心下原约83.0m多年冻土已全部融化.根据210Pb测年,估算该热融湖形成于约890aBP前.在热融湖的影响下,湖心至路基坡脚天然孔之间多年冻土上限深度及多年冻土厚度均发生了很大变化,湖近岸多年冻土上限深度比路基坡脚天然孔多年冻土上限深约0.65m,湖边多年冻土厚度也比路基坡脚天然孔多年冻土厚度薄约60m;湖心至路基坡脚天然孔之间土层在水平方向形成明显的地温差异,在相同深度,湖心下土层地温年平均值比天然孔地温年平均值高5.0℃左右.热融湖作为热量的载体,以二维热传导方式将热量向其周围传递,导致附近多年冻土温度升高,热稳定性降低.     

青藏高原多年冻土区热融滑塌发育特征及规律

在全球气候变暖和高原多年冻土持续退化的背景下,青藏高原多年冻土区热融滑塌现象普遍发育,其形成不仅影响区域生态环境,还可能威胁工程构筑物的稳定性。本文在多年野外调查工作的基础上,结合遥感及历史气象资料对青藏高原多年冻土区热融滑塌的诱发因素、分布特征及演化过程进行了分析。结果表明：冻土活动层滑脱的发生是诱发青藏高原多年冻土区热融滑塌的主要因素,其次为工程扰动和湖水的热侵蚀;活动层滑脱型热融滑塌的发育过程主要包括冻土活动层滑脱的发生、后缘坍塌后退及坡面泥流的形成等三个阶段,热融滑塌形成以后其溯源侵蚀过程将持续数年甚至十几年直到后缘位置地下冰含量明显减少或者消失为止;在空间分布方面,热融滑塌更倾向于分布在坡度较为平缓（3°~8°）的丘陵山地及山麓区域的阴坡一侧;近年来青藏高原多年冻土区热融滑塌呈剧烈增多的趋势,且这种骤增现象主要发生在有极端气温出现的特殊年份,并不是均匀的分布在每一年。研究成果对未来青藏高原工程规划、资源开发及环境协调发展具有重要的指导意义。     

路基施工对青藏高原多年冻土的影响

青藏高原上施工会扰动其下多年冻土的存在状态. 近些年来, 高原上相继修建的大量的线性工程, 这些大型工程的建设必将进行多年冻土区的开挖和夯填, 从而会引起下伏多年冻土的结构发生很大变化. 研究了路基施工对青藏高原多年冻土的影响, 并以青藏铁路、青藏公路沿线典型实例进行分析. 结果表明: 开挖施工扰动最大, 可引起斜坡失稳滑塌、地表积水和热融湖塘等;填土路堤会引起其下伏多年冻土升温, 路基两侧形成的小气候往往起着提高地面温度的作用;挡水、排水设施施工也会导致多年冻土上限下降, 地表沉陷. 可见, 填土路基、开挖、地表工程扰动都会导致多年冻土发生变化, 这些冻土变化对路基稳定必将构成威胁.     

青藏铁路多年冻土区沼泽化斜坡路基稳定性分析

青藏铁路多年冻土斜坡段路基稳定性对铁路长期运营具有潜在的威胁,分析评价当前和未来斜坡路基稳定性可指导路基工程的正确设计和施工,从而保证铁路的安全运营。多年冻土地温变化使斜坡路基稳定性分析不同于普通土路基,其冻融交界面位置是制约斜坡路基稳定性的关键所在。通过对安多试验段3a来的地温监测,分析路基地温变化规律,并预测了未来50a内试验段地温的变化趋势,建立了当前和未来条件下的斜坡路基稳定性模型,计算分析了斜坡路基的稳定性。通过上述研究,取得以下认识和结论:(1)铁路路堤的填筑,引起多年冻土温度场重分布;由于坡向不对称和几何不对称,使得地温场存在不对称;(2)依据冻融界面位置和活动层的地温特征将冻土路基划分为4个不同时期,即冬季严寒期(1~2月)、春夏融化活动期(3~8月)、最大融深期(9~10月)及回冻活动期(11~12月);通过计算对比分析,每年最大融深期的稳定性系数最小;(3)数值分析的预测结果表明,20a以后,安多段试验段路基的多年冻土完全退化,在所预测的第10年最大融深期稳定性系数最小。     

The terrestrial fauna of the Late Triassic Pant-y-ffynnon Quarry fissures,South Wales,UK and a new species of Clevosaurus (Lepidosauria: Rhynchocephalia)

Pant-y-ffynnon Quarry in South Wales yielded a rich cache of fossils in the early 1950s, including articulated specimens of new species (the small sauropodomorph dinosaur Pantydraco caducus and the crocodylomorph Terrestrisuchus gracilis), but no substantial study of the wider fauna of the Pant-y-ffynnon fissure systems has been published. Here, our overview of existing specimens, a few described but mostly undescribed, as well as freshly processed material, provides a comprehensive picture of the Pant-y-ffynnon palaeo-island of the Late Triassic. This was an island with a relatively impoverished fauna dominated by small clevosaurs (rhynchocephalians), including a new species, Clevosaurus cambrica, described here from a partially articulated specimen and isolated bones. The new species has a dental morphology that is intermediate between the Late Triassic Clevosaurus hudsoni, from Cromhall Quarry to the east, and the younger C. convallis from Pant Quarry to the west, suggesting adaptive radiation of clevosaurs in the palaeo-archipelago. The larger reptiles on the palaeo-island do not exceed 1.5?m in length, including a small carnivorous crocodylomorph, Terrestrisuchus, and a possible example of insular dwarfism in the basal dinosaur Pantydraco.     

Définition d'une limite multicritère ; stratigraphie du passage Campanien–Maastrichtien du site géologique de Tercis (Landes,SW France)Definition of a multi-criteria boundary; stratigraphy of the Campanian–Maastrichtian interval of the geological site at Tercis (Landes,SW France)

Lithostratigraphy, physicochemical stratigraphy, biostratigraphy, and geochronology of the 77–70 Ma old series bracketing the Campanian–Maastrichtian boundary have been investigated by 70 experts. For the first time, direct relationships between macro- and microfossils have been established, as well as direct and indirect relationships between chemo-physical and biostratigraphical tools. A combination of criteria for selecting the boundary level, duration estimates, uncertainties on durations and on the location of biohorizons have been considered; new chronostratigraphic units are proposed. The geological site at Tercis is accepted by the Commission on Stratigraphy as the international reference for the stratigraphy of the studied interval. To cite this article: G.S. Odin, C. R. Geoscience 334 (2002) 409–414.     

The effect of water on accessory phase solubility in subaluminous and peralkaline granitic melts

The solubilities of columbite, tantalite, wolframite, rutile, zircon and hafnon were determined as a function of the water contents in peralkaline and subaluminous granite melts. All experiments were conducted at 1035 °C and 2 kbar and the water contents of the melts ranged from nominally dry to approximately 6 wt.% H₂O. Accessory phase solubilities are not affected by the water content of the peralkaline melt. By contrast, solubilities are affected by the water content of the subaluminous melt, where the solubilities of all the accessory phases examined increase with the water content of the melt, up to 2 wt.% H₂O. At higher water contents, solubilities are nearly constant. It can be concluded that water is not an important control of accessory phase solubility, although the water content will affect diffusivities of components in the melt, thus whether or not accessory phases will be present as restite material. The solubility behaviour in the subaluminous and peralkaline melts supports previous spectroscopic studies, which have observed differences in the coordination of high field strength elements in dry vs. wet subaluminous granitic glasses, but not for peralkaline granitic glasses. Lastly, the fact that wolframite solubility increases with increasing water content in the subaluminous melt suggests that tungsten dissolved as a hexavalent species.     

Late Wuchiapingian (Late Dzhulfian,early Late Permian) limestone olistolites within the Tertiary flysch of Glypia Unit (Mount Parnon,central–eastern Peloponnesus,Greece)

Some olistolites reworked in a Tertiary flysch of Mount Parnon (Peloponnesus, Greece) exhibit a Late Permian assemblage, dominated by Paradunbarula (Shindella) shindensis, Hemigordiopsis cf. luquensis and Colaniella aff. minima. This association corresponds to the Late Wuchiapingian (=Late Dzhulfian), a substage whose algae and foraminifera are generally little known. Contemporaneous limestones crop out in the middle part of the Episkopi Formation in Hydra, but they are rather commonly reworked in Mesozoic and Cainozoic sequences. The palaeobiogeographical affinities shared by the foraminiferal markers of Greece, southeastern Pamir, and southern China, are very strong (up to the specific level), and are congruent with the Pangea B reconstructions. To cite this article: E. Skourtsos et al., C. R. Geoscience 334 (2002) 925–931.     

PALEONTOLOGY

正20141596 Liu Yunhuan(School of Earth Sciences and Resources,Chang’an University,Xi’an 710054,China);Shao Tiequan Early Cambrian Quadrapyrgites Fossils of Xixiang Boita in Southern Shaanxi Province(Journal of Earth Sciences and Environment,ISSN1672-6561,CN61-1423/P,35(3),2013,p.39-43,3 illus.,20 refs.)     

GEOCHEMICAL EXPLORATION

正20141719 Chen Zhijun(State Key Laboratory of Geological Processes and Mineral Resources,China University of Geosciences,Wuhan 430074,China);Chen Jianguo Automated Batch Mapping Solution for Serial Maps:A Case Study of Exploration Geochemistry Maps(Journal of Geology,ISSN1674-3636,CN32-1796/P,37(3),2013,p.456-464,2 illus.,2 tables,10 refs.)     

MICROPALAEONTOLOGY

正20140962 Chen Fenning(Xi’an Institute of Geology and Mineral Resources,Xi’an710054,China);Chen Ruiming Late Miocene-Early Pleistocene Ostracoda Fauna of Gyirong Basin,Southern Tibet(Acta Geologica Sinica,ISSN0001-5717,CN11-1951/P,87(6),2013,p.872-886,6illus.,56refs.)     

PETROLOGY

正1.IGNEOUS PETROLOGY20142008Cai Jinhui(Wuhan Center,China Geological Survey,Wuhan 430205,China);Liu Wei Zircon U-Pb Geochronology and Mineralization Significance of Granodiorites from Fuzichong Pb-Zn Deposit,Guangxi,South China(Geology and Mineral Resources of South China,ISSN1007-3701,CN42-1417/P,29(4),2013,p.271-281,7illus.,     

ENVIRONMENTAL GEOLOGY

正20141205Cheng Weiming(State Key Laboratory of Resources and Environmental Information System,Institute of Geographic Sciences and Natural Resources Research,CAS,Beijing 100101,China);Xia Yao Regional Hazard Assessment of Disaster Environment for Debris Flows:Taking Jundu Mountain,Beijing as an