冰碛土体起动泥石流的特征研究

与广泛分布于干旱河谷的宽级配砾石土体特征不同,冰碛土广泛分布在青藏高原地区,属粗大颗粒多、粘粒含量少、摩擦阻力大、粘滞阻力小的宽级配砾石土体。在冰川融雪与降雨的共同作用下冰碛土体可失稳并起动泥石流,形成灾害。针对冰碛土体起动泥石流机理研究薄弱的现状,本文选取波密县帕隆藏布流域的支流嘎弄沟一冰碛土堆积坡面,通过模拟降水与冰雪融水起动冰川泥石流实验,比较不同颗粒组成、不同实验条件下的土体起动泥石流特征,分析其起动成因及力学特性,探讨冰碛土体起动泥石流的机理。研究发现冰碛土体失稳起动泥石流是粘滞阻力降低、孔隙水压力升高、拖曳力与渗流侵蚀共同作用的结果,起动过程受粘土颗粒含量和径流类型的影响。当粘粒含量较高时(>3%),土体通过铲蚀与面蚀形成泥石流;粘粒含量中低时(不高于3%),大部分坡面土体主要经掏蚀与坍塌起动泥石流;粘粒含量过低时(<0.32%),土体难以起动泥石流。在降水作用下土体孔隙水压力迅速增加,易造成土体破坏,起动泥石流;而在冰雪融水的作用下,土体孔隙水压力波动幅度不大时,土体同样可能发生失稳破坏起动泥石流。     

Solute provenance,transport and denudation in a high arctic glacierized catchment

Recent understanding of chemical weathering in glacierized catchments has been focused on mid-latitude, Alpine catchments; comparable studies from the high latitudes are currently lacking. This paper attempts to address this deficiency by examining solute provenance, transport and denudation in a glacierized catchment at 78°N in the Svalbard High Arctic archipelago. Representative samples of snow, glacier ice, winter proglacial icing and glacier meltwater were obtained from the catchment during spring and summer 1993 and analysed for major ion chemistry. Seasonal variations in the composition of glacier meltwater occur and are influenced by proglacial solute acquisition from the icing at the very start of the melt season, and subsequently by a period of discharge of concentrated snowmelt caused by snowpack elution; weathering within the ice-marginal channels that drain the glacier, particularly carbonation reactions, continues to furnish solute to meltwater when suspended sediment concentrations increase later in the melt season. Partitioning the solute flux into its various components (sea-salt, crustal, aerosol and atmospheric sources) shows that c. 25% of the total flux is sea salt derived, consistent with the maritime location of the glacier, and c. 71% is crustally derived. Estimated chemical denudation, 160 meq m⁻² a⁻¹ sea salt-corrected cation equivalent weathering rate, is somewhat low compared with other studied glacierized catchments (estimates in the range 450–1000 meq m⁻² a⁻¹), which is probably attributable to the relatively short melt season and low specific runoff in the High Arctic. A positive relationship was identified between discharge and CO₂ drawdown owing to carbonation reactions in turbid meltwater. © 1997 John Wiley & Sons, Ltd.     

Controls on the location,morphology and evolution of complex esker systems at decadal timescales,Breiðamerkurjökull,southeast Iceland

This paper uses detailed mapping of eskers to address three questions which are important for reconstructing meltwater behaviour beneath contemporary and ancient ice masses: ‘What controls the morphology of simple and complex esker systems?’, ‘How do esker systems evolve through time?’ and ‘Are esker patterns compatible with groundwater controlled hydraulic spacing of esker tunnels?’. Esker crestlines and widths are mapped on the Breiðamerkurjökull foreland for eight time slices between 1945 and 2007, from high resolution (~50 cm) aerial photography, permitting their long‐term morphological evolution to be analysed in a high level of detail. We find that complex eskers develop where meltwater and sediment is abundant, such that sediment clogs channels, forming distributary eskers. Isolated eskers are simpler and smaller and reflect less abundant meltwater and sediment, which is unable to clog channels. Eskers may take several decades to emerge from outwash deposits containing buried ice and can increase or decrease in size when ice surrounding and underlying them melts out. It has been suggested that groundwater–channel coupling dictates the spacing between eskers at Breiðamerkurjökull. Our results do not dispute this, but suggest that the routing of sediment and meltwater through medial moraines is an additional important control on esker location and spacing. These results may be used to better understand the processes surrounding esker formation in a variety of geographical settings, enabling a more detailed understanding of the operation of meltwater drainage systems in sub‐marginal zones beneath glaciers and ice sheets. Copyright © 2015 John Wiley & Sons, Ltd.     

Implications of subsurface thermal–hydraulic–mechanical processes associated with glaciation on Shield flow system evolution and performance assessment

A deep geologic repository (DGR) situated on the Canadian Shield will be subject to long-term climate change that will markedly alter surface conditions as a result of glaciation and permafrost penetration. Systematic, two-dimensional and three-dimensional coupled thermal–hydraulic–mechanical finite-element simulations with varying degrees of coupling, including depth-dependent salinity (represented as a change in groundwater density) and temperature-dependent density and viscosity, were undertaken to address the implications of glaciation on groundwater flow system dynamics as it could affect DGR performance. The modelling domain consisted of a 1.6-km deep sub-regional scale (≈100 km²) fractured Shield flow system. Initial and transient thermal, hydraulic and mechanical boundary conditions were developed from two realizations of the University of Toronto Glacial Systems Model of the last Laurentide glaciation. Results indicate that during the glacial loading/unloading cycle, for this particular conceptual model, there is limited penetration of glacial meltwaters to depth and small residual anomalous hydraulic head. During glacial coverage, the mechanical factor of safety increases in the moderately fractured and sparsely fractured rock mass, but principal effective stress reorientation also occurs. Given the assumed nonglacial in situ state of stress and mechanical properties, the fracture zones were predicted to be less stable under glacial conditions.

Hydrothermal pattern of frozen soil in Nam Co lake basin,the Tibetan Plateau

Hydrothermal processes and the regimes of frozen soil formed in alpine regions with glaciers and lake area are complex and important for ecological environment but have not been studied in Tibet. Based on soil temperature and moisture data from October 2005 to September 2006 collected in the Nam Co lake basin, Tibetan Plateau (TP), those questions were discussed. The mean annual air temperature was −3.4°C with 8 months below 0°C. Air and soil temperature varied between −25.3~13.1°C and −10.3~8.8°C, respectively. Soil moisture variations in the active layer were small with the minimum value of 1.4%, but were influenced greatly by snowmelt, rainfall and evaporation, varying up to 53.8%. The active layer froze later, thawed earlier and was thinner, however, the lower altitude limit of permafrost is higher than that in most areas of TP. The effects of soil moisture (unfrozen water content) on soil temperature, which were estimated through proposed models, were more significant near ground surface than the other layers. The surface soil temperature decreased with snowcover, the effect of cold snow meltwater infiltration on soil thermal conditions was negligible, however, the effect of rainfall infiltration was evident causing thermal disruptions.     

青藏高原东南部贡嘎山海螺沟冰川冰下沉积物形成与变形

冰岩界面的冰川动力学是冰川系统的重要组成部分, 海螺沟冰川地处温暖湿润的海洋环境, 冰川运动速度较快, 冰川底部接近压融点, 是研究冰下过程的较理想地点. 在海螺沟冰川大型磨光面上浅显侵蚀坑内发现了碎屑物质. 对碎屑物质理化特征研究表明: 粒度特征、地球化学与石英砂SEM 分析表明沉积在冰岩界面上的物质来自于冰川底部的底碛层, 而不是冰上环境的产物. 偏光显微镜下观察到的冰下沉积物呈现出一系列塑性变形(微旋转、褶皱)和脆性变形(线性结构、支撑结构、断层)微观结构和构造. 两种变形结构的存在是碎屑物质在形成过程中其含水量波动情况的反映. 冰下碎屑物质是冰下融出、滞碛作用的共同产物. 在整个冰下碎屑物质形成与变形过程中, 由于冰下水系季节性变化带来的冰岩界面上冰川融水含量的波动起了决定性作用.     

2015年夏季南疆地区高温冰雪洪水特征

2015年7月中旬开始至8月初,新疆地区受东移的伊朗高压控制,新疆南疆塔里木河流域及其周边区域遭遇历史同期罕见高温天气.南疆地区和天山山区7月平均气温分别为27.9℃、17.8℃,较常年分别偏高2.3℃、2.6℃,偏高幅度均居历史同期第一位;南疆及天山山区共计42站7月平均气温突破同期历史极值,使该地区从高空到地面不同高度气温都同时升高.0℃层高度都高于雪线高度,导致南疆多条河流发生冰雪消融性洪水,造成不同程度的洪水灾害.此次由高温天气产生的多条河流冰雪消融性洪水,由于具有充足的水热因子,致使南疆多条河流超过警戒流量和保证流量.尼雅河出现有实测资料以来第2位的洪水,阿克苏库玛拉克河发生有实测资料以来第3位的洪水;发生洪水的河流范围之广、持续时间之长历史罕见,叶尔羌河、玉龙喀什河、喀拉喀什河超警戒流量持续时间在半个月以上,叶尔羌河达到25 d.通过对历年冰雪消融性洪水资料分析,洪峰流量和日流量（洪量）与高空温度有较好的相关性,由此建立冰雪消融性洪水预报模型,应用在2015年夏季洪水预报中取得明显的效果,对于今后预报此类洪水提供了有益的借鉴.     

Geochemistry of groundwater in front of a warm‐based glacier in Southeast Greenland

Groundwater in front of warm‐based glaciers is likely to become a more integrated part of the future proglacial hydrological system at high latitudes due to global warming. Here, we present the first monitoring results of shallow groundwater chemistry and geochemical fingerprinting of glacier meltwater in front of a warm‐based glacier in Southeast Greenland (Mittivakkat Gletscher, 65° 41′ N, 37° 48′ W). The groundwater temperature, electrical conductivity and pressure head were monitored from August 2009 to August 2011, and water samples were collected in 2009 and analyzed for major ions and water isotopes (δD, δ¹⁸O). The 2 yrs of monitoring revealed that major outbursts of glacier water during the ablation season flushed the proglacial aquifer and determined the groundwater quality for the next 2–8 weeks until stable chemical conditions were reached again. Water isotope composition shows that isotopic fractionation occurs in both groundwater and glacier meltwater, but fractionation due to evaporation from near‐surface soil moisture prior to infiltration has the most significant effect. This study shows that groundwater in Low Arctic Greenland is likely to possess a combined geochemical and isotopic composition, which is distinguishable from other water sources in the proglacial environment. However, the shallow groundwater composition at a given time is highly dependent on major outbursts of glacier water in the previous months.     

An origin for laminated glacimarine sediments through sea-ice build-up and suppressed iceberg rafting

Laminated glacimarine sediments are observed in visual core logs and x-radiographs from Scoresby Sund and Nansen Fjord, east Greenland. They are mostly underlain and overlain by massive or stratified glacimarine diamicton (Dmm or Dms), which is a product of iceberg delivery of heterogeneous debris and, in Scoresby Sund, reworking by deep-drafted iceberg keels. The laminated sediments are AMS radiocarbon dated to two cold periods since the last, Late Weichselian deglaciation: the Younger Dryas stadial (Milne Land Stadial in east Greenland) and the Little Ice Age. During cold climatic events, multiyear shorefast sea ice ('sikussak') formed in these fjords and trapped the icebergs. Fine-grained, laminated muds (Fl) were deposited in Scoresby Sund when the flux of icebergs was suppressed, but turbid meltwater continued to provide some sediment flux to the fjord systems, varying through time to produce laminations. In Nansen Fjord, thinner and often massive mud layers (Fm) resulted from shorter intervals of sea-ice cover with no ice rafting. Stratified diamicton layers (Dms), which alternate with mud deposition to produce a laminated unit, probably represent intervening times of more open conditions with iceberg rafting. In Scoresby Sund, foraminifera are either absent from the laminated unit or begin to appear towards the end of its deposition. The absence of both benthic and planktonic foraminifera also suggests that multiyear sea ice was covering the core sites. There is no evidence of macrofaunal activity, and bioturbation is absent from the laminated sediments. Satellite data show that multiyear shorefast sea ice is present in several areas of the high Arctic today, and this traps icebergs calved from interior ice-cap drainage basins. Thus, the process of laminated glacimarine sediment formation is likely to be applicable to a number of areas of the modern and Quaternary Arctic.     

壶穴差异风化或风蚀作用成因质疑

过去十年来发表了一系列关于中国东部第四纪冰川地貌的文章,而关于壶穴成因的争论也通过各种媒介报道出来。笔者等建议壶穴仅仅用于表示快速旋转水流在基岩表面形成的近圆筒形的凹坑,以口小肚大底平为典型形态特征,而冰川融水冲蚀形成的壶穴则叫做冰川壶穴。近年来,有些研究者将中国东部花岗岩山脊上的壶穴与差异风化和风蚀作用联系起来。笔者等分析了风化作用和风蚀作用的特点,明确指出：风化作用和风蚀作用并非壶穴形成的原因,唯一可能的成因是快速的河水或冰川融水的旋转水流。因此,在中国南方河床上发现的壶穴既可能是河流流水形成的,也可能是第四纪山谷冰川融水造成的;而中国北方花岗岩山脊上的壶穴只能是曾经覆盖其上的第四纪冰帽在冰川退缩期之冰川融水形成的。所以,花岗岩山脊上的壶穴为冰川壶穴（即冰臼）,可以看作第四纪冰帽的标志。根据中国东部壶穴的分布特征推断：中国东部之北方在第四纪末次冰盛期至少曾经存在着许多冰帽甚至大陆冰川,而其南部边缘至少已经达到山东蒙山以南。