岷江上游叠溪古滑坡坝—堰塞湖研究进展

四川岷江上游叠溪发育有一套厚度超过200 m、保存较为完整的湖相沉积,被定名为叠溪古堰塞湖相沉积,其形成于距今30 ka前,存活了约15 ka,因此记录了青藏高原东缘晚更新世—全新世(包括末次冰期)的重大地质与环境事件。现有研究初步揭示了古堰塞的沉积特征,但对叠溪古滑坡及古堰塞湖形成与演化的系统研究还十分不足。本文通过详细的野外调查,结合现代遥感测绘技术(无人机载LiDAR),构建叠溪古滑坡的三维地质模型,研究了其地质与地貌特征。同时,采用高密度电阻率法ERT,在滑坡体上布设2条长870 m和990 m的测线,探明了滑坡体内部结构特征。通过古堰塞湖相沉积露头和钻孔的调查,结合激光粒度测试,重建了古堰塞湖的范围、规模与沉积特征。在此基础上,通过对古湖相沉积坡面上多级阶地的分析,初步探讨了古堰塞湖的消亡及其对下游史前古聚落变迁的影响。研究结果表明,叠溪古滑坡不仅完全堵塞岷江而且还堵塞了对岸支沟,堆积体方量达到(1 400~2 000)×10⁶ m³。古堰塞湖在滑坡坝后向上游延伸26 km,所形成的最大湖面覆盖面积约21.4 km²,库容蓄水量约1 670×10⁶ m³。叠溪古滑坡-堰塞湖在岷江上游形成了陡峭的河道裂点(Knickpoint),对山区河道与地貌演化具有长期影响。     

岷江上游近两万年前发生了什么事件?

在对岷江1933年叠溪古镇地震滑坡调查研究中,对较场大滑坡上覆盖的较古老的土黄色厚土层进行详细研究,发现并确认这是一套静水环境下的河湖相沉积物,定名为叠溪古堰塞湖相沉积。这套湖相沉积物厚度最大可达200余m,根据14C测试,形成于约两万年以前。此后在叠溪下游以及岷江支流杂谷脑河中又发现了几个古堰塞湖沉积物,测年初步判定,也都形成于距今两万年左右。这一事实揭示两万年以前岷江上游曾发生过一次重大的变动,系列堰塞湖几乎在同一时期出现,形成了特殊的生态环境,消亡过程必然对其下游乃至川西平原环境的演化发生重要影响。堰塞湖沉积物中记载了地质环境和古气候环境变化的信息,是深入系统研究青藏高原前缘地质环境近期演化规律的极为可贵的资料。文中对这些古堰塞湖作了简要介绍,并就一些主要问题进行初步讨论。     

岷江上游近两万年前发生了什么事件?

在对岷江1933年叠溪古镇地震滑坡调查研究中,对较场大滑坡上覆盖的较古老的土黄色厚土层进行详细研究,发现并确认这是一套静水环境下的河湖相沉积物,定名为叠溪古堰塞湖相沉积。这套湖相沉积物厚度最大可达200余m,根据14C测试,形成于约两万年以前。此后在叠溪下游以及岷江支流杂谷脑河中又发现了几个古堰塞湖沉积物,测年初步判定,也都形成于距今两万年左右。这一事实揭示两万年以前岷江上游曾发生过一次重大的变动,系列堰塞湖几乎在同一时期出现,形成了特殊的生态环境,消亡过程必然对其下游乃至川西平原环境的演化发生重要影响。堰塞湖沉积物中记载了地质环境和古气候环境变化的信息,是深入系统研究青藏高原前缘地质环境近期演化规律的极为可贵的资料。文中对这些古堰塞湖作了简要介绍,并就一些主要问题进行初步讨论。     

叠溪地震堰塞湖沉积物特征及演化过程

1933年发生在青藏高原东缘岷江上游叠溪地区的7.5级地震,致岷江干流两岸岩体崩滑堵江,形成叠溪小海子堰塞湖。堰塞湖形成后,水流携带松坪沟流域内的泥砂进入堰塞湖不断沉积,形成具有顶积层、前积层和底积层3层结构的吉尔伯特型扇三角洲。基于野外调查,本文对叠溪堰塞湖三角洲沉积物的沉积特征进行研究,依据沉积物的地貌和沉积特征推断松坪沟流域至少发生过两次大型洪水事件。采用水力学中的水流能量法反演计算,结果表明这两次洪水的最大洪峰流量分别为405.4 m3·s-1和365.4 m3·s-1。叠溪堰塞湖沉积特征与历史洪峰流量的重建,对于了解震后堰塞湖地质环境及演化规律等方面具有重要意义,可为地质灾害等事件的发生频率、危害程度在工程建设方面提供参考。     

岷江叠溪古堰塞湖的研究意义

近年来,在岷江上游及其支流杂谷脑河中发现了多处滑坡古堰塞湖沉积物,并受到广泛关注,但也有不少学者质疑是否是堰塞湖相沉积物.2008年5月12日四川汶川地震引发了几十个规模较大的滑坡堰塞湖,叠溪古堰塞湖展示的重大地质历史事件再次引起学术界广泛的关注.本文根据最新调查、勘查和测试资料对古堰塞湖的形成与消亡过程做了进一步查证...     

基于HEC-RAS及GIS的川西叠溪古滑坡堰塞湖溃决洪水重建

青藏高原东南缘岷江上游地区地质环境条件十分复杂,滑坡堵江灾害及堰塞湖溃决事件频发,重建其灾害演化过程对于地区性防灾减灾和风险控制具有重要指导意义。以川西岷江上游叠溪古滑坡堰塞湖为研究对象,首先利用高精度DEM和ArcGIS软件重建了叠溪古堰塞湖的原始规模,其原始最大湖水面积为1.1×10⁷ m²,相应的湖容量为2.9×10⁹ m³;然后采用经验公式法和HEC-RAS一维水力学模型重建叠溪古堰塞湖溃决洪水的水力学特征。计算结果表明,HEC-RAS模拟的最大溃决洪水洪峰流量为73 060 m³/s,与经验公式法计算结果(74 500~76 800 m³/s,平均值76 000 m³/s)非常接近,误差小于5%。对应的最大洪水深度和流速分别为70.1 m和16.78 m/s,模拟河段的洪水淹没范围约为6.08 km²。综合误差分析推测的溃决洪峰流量误差范围为69 000~81 000 m³/s。叠溪古滑坡堰塞湖溃决洪水在世界范围内是十分罕见的,其最直接的影响是在下游数公里范围的河谷内形成大量带状或台阶状的溃坝堆积体和巨砾石堆积“阶地”,且这种影响仍延续至今,这与前人关于高能洪水水文特征和沉积特征的研究认识高度一致,证明本研究成果是非常可靠的。此外,本研究还表明,HEC-RAS一维水力模型可用于高山峡谷地区古滑坡堰塞湖溃决洪水重建研究,可为青藏高原东南缘岷江上游古环境重建和地貌演化提供参考。     

岷江上游河流阶地发育特征及与古滑坡关系初步分析

河流阶地形成演化及其对滑坡的控制是近年来古滑坡研究的热点问题。笔者在对岷江上游河流阶地和古滑坡实地调查测试的基础上,对岷江上游河流阶地的级序、拔河高度、成因类型等进行了分析,绘制了阶地高程位相图和年龄位相图,并结合阶地和古滑坡年代,讨论了阶地与古滑坡的发育关系等。主要取得了以下认识:1)岷江上游的河流阶地具有分段性,成因主要为气候多期次波动与构造活动共同作用,古滑坡及堰塞湖是影响高山峡谷区河流阶地发育的重要因素;2)叠溪-茂县段在20~30 ka B.P.发生了多处大型古滑坡,其中20 ka B.P.的古滑坡可能主要是气候波动引发,30 ka B.P.发生的古滑坡可能主要受控于构造活动(地震);3)岷江上游大量分布的古滑坡堆积体与阶地发育的叠置关系有待进一步理清,开展该地区的河流阶地级序研究要充分考虑古滑坡和堰塞湖的影响.     

雅鲁藏布江中游晚更新世古堰塞湖群的时空关系探讨

雅鲁藏布江中游堵江事件多发,探索堵江事件之间的关系对理解河流地貌演化有着重要作用。在中游宽谷地区,众多河流堆积阶地中保存着古堰塞湖相沉积物。前人对林芝地区、泽当宽谷和日喀则宽谷的古湖相沉积进行了较为深入的研究,三个宽谷在晚更新世均发育过古堰塞湖,但三个地区古堰塞湖之间的时空关系仍未可知。在上述基础上,对雅鲁藏布江中游不同河段古堰塞湖的坝体位置、成因、海拔及发育年代等进行总结分析。归纳出在雅鲁藏布江中游宽谷河段分别发育着3个独立的古堰塞湖,成因多为冰川/冰碛物堵江。晚更新世不同河段降水和地貌条件差异,冰川规模变化速率不同,可能导致冰川前进壅塞河道时间不一致;但3个古堰塞湖的消亡时间较为接近,其溃决过程可能存在关联。     

岷江叠溪古堰塞湖沉积物中孢粉特征

对岷江上游叠溪古堰塞湖200余米厚的堰塞湖相沉积物进行了大量采样测试分析.主要对湖相沉积物中的孢粉和沉积年代进行了测试.通过测试获得了古堰塞湖沉积物的沉积时间和气候环境特征.古堰塞湖沉积物底部形成时间约3.0万年, 靠近顶部形成时间约为1.5万年前.孢粉测试结果显示, 古堰塞湖沉积物沉积剖面可划分为9个气候环境段: (1)温凉半湿润的针阔叶混交森林草原气候环境; (2)寒冷干旱的针叶森林草原气候环境; (3)温凉半干旱的针、阔叶混交疏林草原气候环境; (4)温暖湿润的针、阔叶混交森林草原气候环境; (5)凉半干的针、阔叶混交疏林草原气候环境; (6)温湿的针叶疏林草原气候环境; (7)温凉半干旱的针阔叶混交疏林草原气候环境; (8)凉半湿润的森林草原气候环境; (9)冷干的疏林草原气候环境.研究成果揭示了青藏高原东部边缘至四川盆地过渡带3.0~1.5万年间的古气候古环境演化特征, 为区域环境研究提供了宝贵的资料.      

岷江上游叠溪混杂堆积体的沉积特征及其成因分析

青藏高原东缘岷江上游叠溪河谷段在地质历史时期发生了一次大规模滑坡堵江事件,形成一个特大型堰塞湖。堰塞湖形成后在晚更新世晚期(约27 ka B.P.)发生了溃决,并在坝体下游形成长约5 km的天然混杂堆积体,判断其为叠溪古滑坡堰塞湖溃决后形成的溃坝堆积。该套溃坝堆积体具有叠瓦构造、孔洞构造、块状构造、杂基构造、支撑—叠置构造及韵律互层构造。从上游至下游,溃坝堆积体的出露厚度逐渐变薄,砾石碎屑成分表现出由粗变细的变化趋势。溃坝堆积体是由高流态灾难性洪流及常态流和河流态两种机制形成,相应地具有两大类沉积相:巨砾层相及砾石层相和砂层相,依据溃坝堆积的地貌结构和沉积相特征可以推断叠溪古滑坡堰塞湖至少发生过一次极其罕见的灾难性溃决洪水事件。     

深港西部通道填海区地下水铜、钒、铊、镉、钨迁移的实验研究

填海工程使滨海地区的地下水物理化学条件改变,导致该区域地下水中重金属浓度升高。本文以深港西部通道填海区为例,采用实验室模拟填海条件的办法,初步探讨了影响填海区地下水重金属迁移的关键因素。模拟实验结果表明,填海区地下水中钨元素含量升高与地下水淡化、淤泥氧化过程以及填料风化有关;铜元素含量升高则与淤泥氧化过程以及填料风化有关;钒元素含量升高与地下水淡化和淤泥氧化过程有关,而其他元素含量升高则主要与填料风化释放有关。     

Breakthroughs in the biodiversity, biogeography, biostratigraphy, and basin analysis of the Beaufort group

Over the past decade researchers working on the rocks of the Beaufort Group in the main Karoo Basin of South Africa have vastly increased our understanding of this important Permo-Triassic sequence. Many new fossil forms have been discovered, allowing for breakthroughs into the biodiversity, biogeography and biostratigraphy of the group. Taxonomic and phylogenetic advances are many and varied, and cover most of the vertebrate taxa, but with emphasis placed on the temnospondyl amphibians, archosauriforms and non-mammalian synapsids, in particular the anomodontia. Biostratigraphic breakthroughs have centered on the Middle Permian Eodicynodon and Tapinocephalus assemblage zones, the Late Permian Dicynodon Assemblage Zone, and the Triassic Lystrosaurus and Cynognathus assemblage zones. Correlation of these biozones with better dated sequences in Europe, Russia and China has allowed for many chronostratigraphic refinements, which are in turn vital for sequence stratigraphical analysis of the basin fill. Based on fossil data, both the lower (Ecca–Beaufort) and upper (Beaufort–Molteno) contacts of the group have been proved to be highly diachronous. The refined chronostratigraphic framework has also allowed for a better analysis of the basin evolution through time, particularly in terms of the correlation of external stimuli that affect basin sedimentation patterns.     

藏北羌塘丁固—加措地区康托组的时代

自西藏区域地质调查大队创建康托组以来,康托组岩石地层单位广泛应用于羌塘地区,普遍认为其时代为新近纪.笔者于丁固-加措地区的康托组地层中采获古近纪轮藻化石Obtusocharat sp.,O.lanpingenis,Gyrogona qinajiangica和部分孢粉化石,并在康托组底部安山岩中获K-Ar年龄65.1～66.5Ma.上述轮藻组合与同位素年龄指示的地层时代为古新世-始新世,据此将测区康托组的时代确定为古近纪.由于测区康托组之上被唢纳湖组或鱼鳞山组角度不整合覆盖,因此康托组时代的确定不仅进一步完善了测区新生代地层系统,还指示测区在康托组与唢纳湖组或鱼鳞山组之间发生了一次强烈的构造运动.     

新疆阿图什市木吉地区木吉群孢粉化石的发现

新疆维吾尔自治区阿图什市木吉地区邻近帕米尔,是印度板块与欧亚板块碰撞挤压应力最集中的地区,地层变质和变形强烈,研究基础薄弱。木吉群由变质砂岩、板岩、千枚岩、石英岩、钙质石英岩、变粒岩、二云石英片岩、大理岩等组成,一直未发现任何化石。最近,笔者在木吉乡的喀拉足克沟和阿拉木陶沟的粉砂岩、钙质粉砂岩中发现了一些植物管胞片和孢粉化石:Gran-ulatisporites sp.,Cycloranisporites sp.,Verrucosisporites sp.,Pityosporites sp.,Punetatosporites sp.,Leiotriletes sp.,Apicu-latisporites sp.,Platysaccus sp.,Cycodopites sp.等。从地层接触关系和孢粉化石的整体面貌看,木吉地区含上述孢粉化石的木吉群的时代可能为泥盆纪—石炭纪。     

西藏阿里札达盆地上新统中犀类化石的发现及意义

首次在西藏阿里札达盆地上新世河湖相沉积地层中发现了犀类化石，对其基本特征进行了描述，初步鉴定为犀类额鼻角犀亚科第三庶骨化石，在同一层位中还采集了大量孢粉、微体古生物和植物化石。结合区域地质特征和产出犀类化石地层的沉积学特征等的分析，认为札达盆地上新世时代表着温暖湿润向寒冷潮湿-温和干旱的气候变化过程。这一发现有助于进一步认识青藏高原新近纪上新世的生物演化、气候变化和构造活动，为研究青藏高原新近纪以来的生物进化、湖泊与河流演化、气候变化．古地理与古环境变迁，以及新生代地层的划分对比等提供了新资料。     

Geochronology of the Dovyren intrusive complex, northwestern Baikal area, Russia, in the Neoproterozoic

The paper reports newly obtained data on the geochronology of the Dovyren intrusive complex and associated metarhyolites of the Inyaptuk Formation in the Synnyr Range. The data were obtained by local LA-ICPMS analysis of zircons in samples. The U-Pb age of olivine-free gabbronorite from near the roof of the Yoko-Dovyren Massif is 730 ± 6 Ma (MSWD = 1.7, n = 33, three samples) is close to the estimated age of 731 ± 4 Ma (MSWD = 1.3, n = 56, five samples) of a 200-m-thick sill beneath the pluton. These data overlap the age of recrystallized hornfels found within the massif (“charnockitoid”, 723 ± 7 Ma, MSWD = 0.12, n = 10) and a dike of sulfidated gabbronorite below the bottom of the massif (725 ± 8 Ma, MSWD = 2.0, n = 15). The estimates are also consistent with the age of albite hornfels (721 ± 6 Ma, MSWD = 0.78, n = 12), which was produced in a low-temperature contact metamorphic facies of the host rocks. The average age of the Dovyren Complex is 728.4 ± 3.4 Ma (MSWD = 1.8, n = 99) based on data on the sill, near-roof gabbronorite, and “charnockitoid”) and is roughly 55 Ma older than the estimate of 673 ± 22 Ma (Sm-Nd; [13]). The U-Pb system of zircon in two quartz metaporphyre samples from the bottom portion of the Inyaptuk volcanic formation in the northeastern part of the Yoko-Dovyren Massif turns out to be disturbed. The scatter of the data points can be explained by the effect of two discrete events. The age of the first zircon population is then 729 ± 14 Ma (MSWD = 0.74, n = 8), and that of the second population is 667 ± 14 Ma (MSWD = 1.9, n = 13). The older value pertains to intrusive rocks of Dovyren, and the age of the “rejuvenated” zircon grains corresponds to the hydrothermal-metasomatic processes, which affected the whole volcano-plutonic sequence and involved the serpentinization of the hyperbasites. This is validated by the results of Rb-Sr isotopic studies with the partial acid leaching of two serpentinized peridotite samples from the Verblyud Sill. These studies date the overprinted processes at 659 ± 5 Ma (MSWD = 1.3, n = 3).     

Sedimentary structures in the Lower Greensand of the Weald,England, and Bas-Boulonnais,France

Study of the cross-stratification and other sedimentary structures in the Lower Greensand of the Weald, England, and Bas-Boulonnais, France, indicates that the sediments were deposited by the lateral migration of sand waves in a neritic sea. Comparison of the Lower Greensand sea with the modern North Sea was attempted. If those sediments were deposited as a result of tidal current similar to the present-day North Sea then the Lower Greensand shoreline could be deduced as running northwest-southeast, indication that the western part of the London Platform was submerged.     

Pressure Increases, the Formation of Chromite Seams, and the Development of the Ultramafic Series in the Stillwater Complex, Montana

This paper explores the hypothesis that chromite seams in theStillwater Complex formed in response to periodic increasesin total pressure in the chamber. Total pressure increased becauseof the positive V of nucleation of CO₂ bubbles in the melt andtheir subsequent rise through the magma chamber, during whichthe bubbles increased in volume by a factor of 4–6. Byanalogy with the pressure changes in the summit chambers ofKilauea and Krafla volcanoes, the maximum variation was 0•2–0•25kbar, or 5–10% of the total pressure in the Stillwaterchamber. An evaluation of the likelihood of fountaining andmixing of a new, primitive liquid that entered the chamber withthe somewhat more evolved liquid already in the chamber is basedupon calculations using observed and inferred velocities andflow rates of basaltic magmas moving through volcanic fissures.The calculations indicate that hot, dense magma would have oozed,rather than fountained into the chamber, and early mixing ofthe new and residual magmas that could have resulted in chromitecrystallizing alone did not take place. Mixing was an important process in the Stillwater magma chamber,however. After the new magma in the chamber underwent {smalltilde}5% fractional crystallization, its composition, temperature,and density approached those of the overlying liquid in thechamber and the liquids then mixed. If this process occurredmany times over the course of the development of the Ultramaficseries, a thick column of magma with orthopyroxene on its liquiduswould have been the result. Thus, the sequence of multiple injections,fractionation, and mixing with previously fractionated magmacould have been the mechanism that produced the thick bronzitecumulate layer (the Bronzitite zone) above the cyclic units.     

贵州安顺地区岩腊片区水淹坝岩溶内涝成因分析

水淹坝岩溶内涝是安顺市西秀区发育最大范围的岩溶内涝,严重制约了当地经济发展。本文以岩溶地下水系统为单元,通过开展1:10000水文地质调查、地球物理勘探、水文地质钻探等手段,查明内涝所在区的岩溶发育特征、水文地质条件。在此基础上分析得出,水力坡度小、岩层倾角缓造成地下河管道淤塞;人类工程活动使有水落水洞口堵塞,加之广阔的集雨面积和连续的强降雨是造成水淹坝岩溶内涝的主要原因。通过对水淹坝内涝成因分析,为岩溶内涝灾害综合整治提供参考依据。     

Development of the Sumdo Suture in the Lhasa Block, Tibet, China

The Qinghai–Tibet plateau is a composite continental fragment formed by collision of multiple terranes and island arcs.The Lhasa terrane,which is located in the central part of the plateau,is bounded by the Yarlung–Zangbo suture to the south and Bangong-Nujiang suture to the north.An E–W–trending belt of(ultra)-high pressure eclogite was discovered in the Sumdo region of the Lhasa terrane.Careful field studies combined with petrological,geochemical and isotopic analyses show that the Sumdo eclogites mark a Carboniferous–Permian suture zone,at least 100 km long,containing ophiolite fragments,eclogites and Indosinian post–orogenic granitoids.This suture divides the Lhasa block into a northern and southern segment.Sumdo eclogite occurs about 200 km east of Lhasa city,and extends over 100km in an E–W direction.Sumdo eclogites were accompanied by garnet amphibolite and plagioclaseamphiboliteformedbyretrograde metamorphism of the eclogites.The eclogites were derived from oceanic basalts.LA–ICPMS U–Pb dating of zircon from the Sumdo eclogites indicates a Permian metamorphic age(260–270 Ma)and a Carboniferous protolith age of 303±4.8 MaThe ophiolite fragments in the Sumdo suture zone are composed of the ultramafic rocks,MORB–type basalt,OIB–type basalt and island arc basaltic andesite,some of which are intruded by post-collisional granites.The ultramafic body,a typical tectonic block in the suture zone,is completely serpentinized.Its geochemical features suggest that it is composed of harzburgite,typical of depleted mantle peridotite.The MORB and OIB–type basalts crop out in the Chasagang Formation,and the basaltic andesite crops out in the Leilongku Formation,both of which make up the Sumdo Group.Zircons from the OIB–type basalt with typical magmatic characteristics yield an average U–Pb age of306(95%)Ma,suggesting formation in a Paleo–Tethyan basin in the Carboniferous.U–Pb dating of zircon from the basaltic andesites yielded a concordant age of 265±3.1Ma,similar to the metamorphic age(266–270 Ma)of the eclogites,suggesting formation during subduction of the oceanic crust.Indosinian granodiorite with an age of194±4.3 Ma crops out north of the Sumdo suture.These granodiorites are similar to the late Indochina granites in the Lhasa block,and most likely formed during continent-arc collision or during closure of the Paleo-Tethyan Ocean.A four–stage model for the evolution of the Sumdo Paleo–Tethyan suture is proposed:1)From the Ordovician to the Devonian Gondwanaland was part of an epicontinental sea;2)In the Carboniferous,continental rifting produced a local basin,which then evolved into a Paleo-Tethyan ocean basin,dividing the Lhasa block into two segments;3)From the Permian to the early Triassic,Paleo-Tethyan oceanic crust was subducted northward and;4)In the middle Triassic and early Jurassic,the two fragments collided to form the modern Lhasa block.