河流堰塞的地貌响应

堰塞作为一种极端地表过程,深刻影响着河流地貌的变化,特别是河流纵剖面的变化。其对河流纵剖面的影响主要体现在两方面:一方面,堰塞坝将抬高局地的侵蚀基准面,阻碍了上游河道侵蚀,形成河流裂点;另一方面,堰塞坝溃决往往形成大型/巨型洪水,造成下游河道和岸坡的剧烈侵蚀。稳定的堰塞坝形成后,在1~105 a的时间尺度上对河流裂点的发育以及河流纵剖面变化上甚至会超过构造、气候和岩性作用,占据主导。本文在简要概述堰塞地貌相关概念的基础上,介绍了部分河流堰塞的研究方法和案例,以及河流堰塞的发育过程和研究意义。目前多仅从堰塞坝与河流纵剖面的空间关系的相关性来论证其地貌响应,并且发现一些堰塞坝与河流纵剖面的相关性,但是也有一些古堰塞坝对现代河流纵剖面的影响并不显著,原因可能与堰塞坝规模、溃决洪水次数、堵江的持续时间和距今年代的不同有关,目前还缺乏深入研究。     

考虑河床坡度和泄流槽横断面影响的堰塞坝溃决过程试验研究

针对缺乏地形条件和工程处置措施对堰塞坝溃决过程影响研究的现状,采用4种河床坡度(0°、1°、2°、3°)和3种泄流槽横断面型式(三角形、梯形、复合型),开展了堰塞坝溃决的模型试验。通过分析堰塞坝的溃决流量、溃决历时、溃口发展和坝体纵截面演变过程,研究了不同河床坡度和泄流槽横断面对堰塞坝溃决过程的影响规律。试验结果表明:(1)堰塞坝溃决过程可分为3个阶段。阶段Ⅰ:溃口形成阶段,溃决流量较小;阶段Ⅱ:溃口发展阶段,水流下蚀及侧蚀强烈,溃决流量到达峰值;阶段Ⅲ:衰减-平衡阶段,粗化层形成,溃口停止发展。(2)河床坡度增加意味着下游坝坡、坝顶及泄流槽的坡度增加,导致水流侵蚀能力增强,溃口下切迅猛,因此在0°～3°范围内河床坡度越大,峰值流量越大,峰现时间越早,溃决流量过程曲线越趋于“高瘦型”,且残留坝高越小。(3)泄流槽横断面型式不同导致其槽深、槽宽和侧坡坡度不同,进而影响溃口发展和溃决流量。三角形槽的水土作用面积小,溃口下切及展宽速率最高,峰值流量最大,峰现时间最早;梯形槽的槽底高程最高,水土作用面积最大,溃口下切速率最低,峰现时间最晚;而复合槽介于前两者之间。试验成果将为堰塞坝应急抢险和工...     

雅砻江流域河道高程剖面上的堰塞坝印记

堰塞坝会对山区河流的纵剖面产生强烈扰动,在某些情况下,堰塞坝造成的河流纵剖面变陡很容易与构造作用下基准面下降的迁移裂点混淆.然而,在何种程度下堰塞坝会影响基于地貌测量的构造分析还没有系统的研究.因此本文选取青藏高原东缘的雅砻江流域为研究对象,利用遥感影像解译,结合数字高程模型(DEM),来研究堰塞坝对河流纵剖面的影响....     

滑坡堰塞坝堆积形态影响因素离散元分析

滑坡是形成堰塞坝的最主要原因,在地震、降雨、冰雪融水等作用下均可形成滑坡堰塞坝,而滑坡堰塞坝的堆积形态、范围等对评价堰塞坝的稳定性有着重要的影响.通过离散元方法(DEM),系统分析了三维条件下滑动距离、滑面出口宽度、滑面倾角、河床倾角、河谷形状对堰塞坝堆积形态的影响.研究结果表明:滑动距离和出口宽度对坝体高度影响最大;...     

山区下切河流地貌演变机理及其与河床结构的关系

为研究河床结构在下切性河流地貌演变过程中所起到的作用与影响机制,对中国典型下切性河流区域的地貌特征与河床结构发育进行了调查与统计分析.结果表明,当河流剧烈下切使得河谷边坡超过临界坡度后,易于失稳而发生大规模的崩塌滑坡现象,河流演变从而进入下切拓宽阶段.大量边坡物质进入河道,促进了河床结构的发育,能够维持较高的河道纵坡降...     

基于地貌特征的滑坡堰塞坝形成敏感性研究

滑坡堰塞坝是由斜坡失稳堵塞河道而形成的天然坝体,且易溃坝诱发洪水,对沿岸群众生命财产构成巨大的威胁。为提升主动减灾防灾能力,急需构建了一种快速预测与判断滑坡堵江成坝能力的方法。通过文献资料查阅,结合遥感技术,提取了70处典型滑坡的地貌特征参数,其中50处为堵江成坝滑坡。运用K-S检验和M-W U检验方法分析了滑坡地貌特征因子的敏感性,利用Boruta算法确定了因子重要度,筛选了滑坡体积、面积、高差、长度及河宽共5个地貌特征参数。基于此,利用Bayes判别法与逻辑回归方法,分别建立了滑坡堰塞坝形成的预测模型,准确率超过90%。选取高重要度且差异显著的因子,利用比值法建立了滑坡堵江成坝阈值判据,实现了滑坡堰塞坝形成的快速判定。统计不同诱因下滑坡地貌特征,对比V-W_r经验公式,确定了滑坡堰塞坝形成与诱因间的关系,为进一步构建不同诱因下滑坡堰塞坝形成预测模型提供了技术支撑。     

小型水坝拆除后河貌演变模拟分析——以西河水坝为例

小型水坝随着服役时间的增长,其面临的安全、经济和生态方面问题日益突出,针对一些修复价值较低的病险水坝,实施降等或报废拆除已成为一种综合最佳的管理措施。拆坝后,原库区大量淤沙无控释放将改变原有河道形态,对水生生物栖息地造成影响。为预测拆坝后河道在不同时间尺度上的变化特征,以长江流域乌江水系内的西河水坝为研究对象,建立二维水沙数学模型,分别研究了拆坝后水沙输运造成的短期和长期河床形态变化。结果表明:拆坝后短期内,坝址上游主河道发生了强烈的冲刷下切,且水库淤沙前缘部分出现了显著的淤积抬高,相比而言,坝址下游河床变化并不明显,只有坝下河段及河口附近出现较显著的泥沙淤积;在拆坝后长期的河床演变过程中,坝址上下游河道均发生了不同程度的冲刷下切,拆坝2年后下游河床逐渐趋于稳定,而上游主河道由冲刷下切转化为冲淤交替的演变趋势,河床形态不断调整变化。本研究可为病险坝和小水电报废拆坝后的河道治理、水生生物栖息地修复提供参考依据。     

滑坡型堰塞湖形成与保留条件分析——基于文献总结和青藏高原东缘南北向深切河谷研究

在青藏高原东缘的南北向深切河谷内发育大量大型的、可保留万年甚至数万年的古堰塞湖沉积.是什么原因促使这些古堰塞湖形成和长久保留呢？本文从构造、气候、堰塞湖结构、构造等方面探讨了该问题.从构造地貌角度来看,青藏高原向东的构造挤出作用控制了其东缘特殊的南北向河流系统.该系统流经区域具有频发的地震和复杂的深切河谷地貌,是形成大型堰塞湖的有利位置.当堰塞湖形成后,其体积、集水区面积、堰塞坝的高度、长度、内部结构均影响着堰塞湖的稳定性.大型的、串珠状堰塞湖构成大型的、连续的“阶梯-深潭”系统,形成重要的河流裂点,有效的消耗了水流动能,延缓堰塞湖的损坏.从气候角度来看,四万年以来气候变化与堰塞湖的形成及保留关系密切.40～25ka的间冰阶降雨丰富、高原湖面升高、河流卸载能力较强.这一时期丰富的降雨和河流深切作用易引起滑坡和堵塞事件.25～15ka的冰期,河流卸载能力减弱而堆积能力增强,有利于堰塞湖的保存.全新世以来,气候变暖伴随着冰川融化与河流卸载能力增强,促使早期堰塞湖发生快速消亡.从堰塞坝的组成来看,地震引起的滑坡和岩崩是堰塞坝重要物质来源,可形成良好而坚固的堰塞坝体.其受到流水切割易出现窄深型溃口,使得湖相地层以阶地形式保留下来.最后,本文从地球系统的角度谨慎的探讨了堰塞湖这一特殊地表剥蚀-沉积过程所蕴含的构造-气候耦合的意义.     

黔江观音岩滑坡特征与治理

由于黔江河床大量开采巨型块石作建材,河流急速下切滑坡体下卧湖相粘土层,形成新的临空面,观音岩老滑坡体失稳复活.文章从恢复自然环境的思路入手,提出了采用"多级多期谷坊坝及防冲抗滑挡墙”为主体的治理工程方案.该方案发挥谷坊坝阻流降速作用,利用河流的淤积功能,使观音岩段河床逐步恢复到滑坡活动前的状态,有效地遏止河流下切,消除粘土层临空面,真正起到防灾减灾的作用.     

正反粒序结构条件下滑坡堰塞坝破坏模式研究

滑坡堰塞坝是大型滑坡堆积体堵塞河道形成的土石坝。正、反粒序结构作为大型远程滑坡所特有的2种具有显著差异的地质结构特征,2种情况下坝体的破坏模式差异及稳定性影响因素亟需试验研究。文章通过室内水槽物理模型实验,对比不同粒径、不同结构的滑坡堰塞坝坝体的破坏过程差异,探究了正、反粒序结构条件下堰塞坝的稳定性差异、破坏模式及影响因素。研究结果表明：（1）堰塞坝破坏模式的变化取决于浸润线在下游坡面的出露位置,相比上游水位有一定的延迟性;（2）正、反粒序堰塞坝的破坏模式取决于坡体渗流与下游坡面临界起动坡降的关系;（3）细砂层的位置分布,不同埋深细砂层的起动临界坡降差异和细砂与中粗砂的孔隙率差异是造成正、反粒序坝体破坏差异的主要原因。该研究成果可为大型滑坡堰塞坝的防灾减灾提供理论指导。     

Stability of landslide dams and development of knickpoints

The Wenchuan earthquake triggered many landslides and numerous avalanches and created 100 odd quake lakes. The quake lakes may be removed or preserved. The removal strategy was applied to several large landslide dams, which were dangerous because massive amounts of water pooled up in the quake lakes. The dams could eventually fail under the action of dam outburst flooding, potentially endangering the lives of people in the downstream reaches. This paper studied the stability of landslide dams and the development of knickpoints by field investigations and experiments, and analyzing satellite images. The study concluded that if landslide dams were preserved, they would develop into knickpoints and act as a primary control of riverbed incision and, thus, reduce the potential of new landslide. The stability of landslide dams depends mainly on the development of the step-pool system and stream power of the flood flow. If a landslide dam consists of many boulders, a step-pool system may develop on the spillway channel of the dam, which would maximize the resistance, consume most of the flow energy and consequently protect the dam from incision. The development degree of the step-pool system is represented by a parameter S _p, which was measured with a specially designed instrument. A preservation ratio of landslide dams is defined as the ratio of preserved height after flood scouring to the original height of the dam. For streams with peak flood discharge lower than 30 m³/s, the preservation ratio is linearly proportional to S _p. For rivers with a peak flood discharge higher than 30 m³/s (30–30,000 m³/s), the minimum S _p value for stable channel increases with log p, in which p is the unit stream power. For a landslide dam with a poorly developed step-pool system, S _p is smaller than the minimum value and the outburst flood incises the spillway channel and causes failure of the dam. For preserved landslide dams, sediment deposits in the quake lakes. A landslide dam may develop into a knickpoint if it is stabilized by long-term action of the flow. Large knickpoints can totally change the fluvial processes and river morphology. Uplift of the Qinghai–Tibetan Plateau has caused extensive channel bed incision along almost all rivers. For many rivers, the incision has been partly controlled by knickpoints. Upstream reaches of a knickpoint have a new and unchanging base level. This brings about a transition from degradation to aggradation and from vertical bed evolution to horizontal fluvial process. Multiple and unstable channels are prominent in the reaches, upstream of the knickpoints. If hundreds of landslide dams occurred simultaneously on a reach of a mountain river, the potential energy of bank failure and the slope erosion would be greatly reduced and sediment yield from the watershed may be reduced to nearly zero. The quake lakes may be preserved long term and become beautiful landscapes. Streams with long-term unfilled quake lakes have good aquatic ecology.     

基于河长—坡降指数的滑坡堵江事件自动识别

由于本身特征的复杂差异性和背景环境信息干扰,目前地质灾害自动识别难度较大,尚无法满足应用需求。利用算法自动提取某类地质灾害普遍具备且明显区别于周围地物的特征,是实现地质灾害自动识别的有效途径。一定规模的滑坡堵江事件常通过链式过程在山间河谷形成裂点等诸多微地貌特征,成为其遥感解译和现场调查的重要标志。本文从河流地貌演化角度出发,以河流裂点作为滑坡堵江的普遍地貌特征,提出了基于河长-坡降指数（Stream Length-gradient index,SL) 的滑坡堵江事件自动识别方法,并通过GIS程序设计和编写提供了相应功能模块。以DEM、遥感影像和区域地质图为数据源,利用该方法在西藏亚东县康布麻曲上游流域开展应用分析,得到以下结论:针对1:5万DEM数据,采样点计算间隔设定为300m比较合理,能够同时满足降低数据误差和突出地形差异的要求;研究区中不同因素按照对河流地貌的改造程度,排序为滑坡堵江>基岩变化>构造活动;经验证研究区滑坡堵江事件自动提取的正确率达85.71%,表明在高山峡谷地区,基于河长—坡降指数开展滑坡堵江事件自动识别具有可行性,效果理想。     

Coupling fluvial processes and landslide distribution toward geomorphological hazard assessment: a case study in a transient landscape in Japan

This study quantified the relationship among deep-seated gravitational slope deformations (DGSDs), landslides, and river rejuvenation in the upper reaches of the Kumano River in the Kii Mountains of Japan, an area of frequent bedrock landslides. River profiles and hillslope landforms were examined, and high-resolution digital elevation models (DEMs) were used to identify DGSDs and landslides. Many of the deep-seated landslides were associated with rainstorms in 1889 and 2011. Landslide volumes were related to landslide areas on the basis of 52 deep-seated landslides that failed during the 2011 rainfall, providing basic data for landscape denudation and sediment yield. River rejuvenation occurred stepwise, incising moderate relief paleosurfaces and forming two series of knickpoints and V-shaped inner gorges that are up to 400-m deep. More than 65% of DGSDs and 75% of the landslides were located in association with the incised inner gorges along the peripheries of the paleosurfaces or were entirely contained within the inner gorges. DGSDs and landslides associated with the incised inner valley slopes tended to be larger than those developed within the paleosurfaces and may be long-term transient hillslope responses to river incision. Hillslope undercutting caused by rejuvenated river incision may play an important role in long-term slope stability and distribution of mass movements, and could serve as an indicator of landslide hazard.     

Morphological analysis and features of the landslide dams in the Cordillera Blanca,Peru

Global warming in high mountain areas has led to visible environmental changes as glacial retreat, formation and evolution of moraine dammed lakes, slope instability, and major mass movements. Landslide dams and moraine dams are rather common in the Cordillera Blanca Mountains Range, Peru, and have caused large damages and fatalities over time. The environmental changes are influencing the rivers’ and dams’ equilibrium, and the potential induced consequences, like catastrophic debris flows or outburst floods resulting from dam failures, can be major hazards in the region. The studies of past landslide dam cases are essential in forecasting induced risks, and specific works on this topic were not developed in the study region. Reflecting this research gap, a database of 51 cases and an evolution study of landslide dams in the Cordillera Blanca Mountains is presented. The main morphometric parameters and information of the landslide, the dam body, the valley, and the lake, if any, have been determined through direct and indirect survey techniques. Low variability in some of the main morphometric parameter distributions (valley width and landslide volume) has been shown, most likely due to an environmental control connected to the regional tectonic and glacial history. In order to analyze present and future landslide dam evolution, a morphological analysis was carried out using two recently developed geomorphological indexes employed on the Italian territory. The results of the Cordillera Blanca analysis have been compared with a large Italian landslide dam inventory, highlighting as much the differences as the similarities between the two datasets. The long-term geomorphological evolution changes are evaluated. Many of the stable dams are in disequilibrium with their surrounding environment and their classification result is of “uncertain determination.”     

Formation process of a large paleolandslide-dammed lake at Xuelongnang in the upper Jinsha River,SE Tibetan Plateau: constraints from OSL and <Superscript>14</Superscript>C dating

A large number of the landslide dams located on the major rivers at the southeastern margin of the Tibetan Plateau have been previously identified through remote sensing analysis and field investigations. The Xuelongnang paleolake was one of the lakes formed by these landslide dams in the upper Jinsha River, where the association of a relict landslide dam, lacustrine sediment, and outburst sediment is well preserved. This preservation provides an opportunity to better understand the formation, evolution, and longevity of a large landslide-dammed lake in the upper Jinsha River. It was inferred that the Xuelongnang dammed lake may have been formed by an earthquake-induced paleoavalanche. The surface area of the lake at its peak was estimated at 7.0?×?10⁶ m², and the corresponding volume was approximately 3.1?×?10⁸ m³. Two outburst flood events were determined to have occurred during the life span of the lake. Based on the 18 ages obtained from optically stimulated luminescence (OSL) and carbon-14 (¹⁴C) dating combined with stratigraphic sequences observed in the field, the paleolandslide-dammed lake was formed at approximately 2.1 ka and subsequently breached locally. The dammed lake was sustained for a period of some 900 years based on the chronological constraining. This study confirms that a major landslide-dammed lake can be sustained for at least hundreds of years and breached by several dam breaks in multiple periods, which contributed to the preservation of the knickpoints at millennial scale along the major rivers in the study area.     

Mechanism of the giant Seimareh Landslide,Iran, and the longevity of its landslide dams

Seimareh Landslide (SL) is globally recognized as one of the largest rock mass movements in the world. It is located along the border of Ilam and Lorestan provinces in southwest Iran, in the heart of the Zagros Mountain Range. There are controversial findings about the mechanism of the landslide formation. This field work study reviewed the possible mechanisms of failure and analyzed post-failure geomorphic features. Drainage pattern disturbance in the depositional region and consequent dammed lake formation are among the most significant characteristics of these features. Seimareh, Jaidar and Balmak are three large landslide-dammed lakes. The present study analyzed the processes responsible for the formation and erosion of the Jaidar and Seimareh Landslide dams using the available annual sedimentation and field measurements of the sediment deposited in these lakes. The results showed that the SL dam has been formed about 935 years after the landslide event. Detailed field investigations indicated a specific hydro-morphological condition in the landslide area. The results implied that the main causes of the failure were probably the particular hydro-morphological characteristic of the landslide source area together with the enormous eroding energy resulted from merging of two high-flow rivers which eroded the base of the southern flank of Kabir-kuh Mountain. However, the unusual size of the landslide suggests that an external factor, e.g., a huge earthquake, might have triggered the failure.     

堵江滑坡作坝主要是工程地质问题及实例

国内外大量的文献资料和作者的野外现场调查表明,滑坡堵江成坝形成堰塞湖在山区一带广泛发育研究发现堵江滑坡作坝存在的地质问题,主要包括坝体的渗透变形、稳定性、沉降及不均匀沉降和砂土液化问题。对上术叶质问题进行探讨,并对堵江滑坡坝进行实例分析,对开发利用滑坡堵江形成堰寒湖藏的丰富水能资源具有指导作用。     

堵江滑坡作坝的主要工程地质问题及利用情况分析

国内外大量的文献资料和作者野外现场调查表明:滑坡堵江成坝形成堰塞湖在山区一带广泛发育,研究发现堵江滑坡作坝存在的工程地质问题主要包括渗透变形、稳定性、沉降及不均匀沉降和砂土液化问题。文中对上述工程地质问题进行了探讨,并对滑坡坝的利用情况进行了实例分析,为开发堵江滑坡坝、堰塞湖蕴含的丰富水利水电资源起指导性作用。     

滑坡堰塞湖溃决风险与过程研究进展

滑坡堰塞湖是山区常见的一种自然灾害,对其溃决风险与过程的科学认知和合理评估是应急处置的关键。外荷载作用下滑坡堰塞体的力学响应、滑坡堰塞湖渐进破坏机理与溃决洪水预测理论是滑坡堰塞湖风险评估研究领域的关键科学问题。本文围绕滑坡堰塞湖形成后的溃决风险与过程展开综述,从定性和定量的角度分别对堰塞湖危险性评价方法进行分析总结,从小尺度、大尺度和超重力场试验技术的角度总结了堰塞湖的溃决机理、溃决过程及其影响因素,从数学方法的角度对堰塞湖溃决洪水预测中经验公式法、简化和精细化数值模拟方法的进展进行总结评价。然而,国内外关于滑坡堰塞湖风险评估领域的研究仍处于起步阶段,空-天-地一体化监测技术、堰塞湖危险性评价中的不确定性问题、堰塞体材料冲蚀特性与溃决机理、堰塞湖溃决洪水精细化模拟等将是未来的重点研究方向。本综述可为堰塞湖防灾减灾和流域水工程风险管理提供有价值的参考。