黄河玛曲砾质网状河段河间湿地形态特征及发育程度

河间湿地是网状河流体系中与多河道系统同等重要的地貌单元,其特征和发育程度与河道系统共同决定着网状河流的特性。本文以黄河玛曲网状河段作为研究对象,利用高分辨率Google Earth影像对研究河段河道与河间湿地等微地貌单元进行提取,利用湿地面积与湿地数对河间湿地的组成进行了分析,利用河间湿地面积占比、岸线密度、分汊点密度3个地貌参数,对河间湿地群体（河间湿地与分支河道特定组合体）的平面形态及多河道发育程度进行了研究。结果表明,河间湿地个体以中小型的为主,河间湿地群体则以大型和巨型的为主。河间湿地群体的发育程度与河间湿地群体面积（S_u）明显相关,河间湿地面积占比（P）随S_u的增大而增大,P值70%是河间湿地发育成熟的指标,而P值80%基本是河间湿地发育的上限值,此时河间湿地与分支河道基本达到动态平衡态。岸线密度、分汊点密度随S_u的增加呈减小趋势,这种变化主要是由于不同大小河间湿地群体中河道发育过程差异导致。黄河玛曲段河间湿地群体的形成在于弯曲主河道的主导作用、地形限制因素削弱导致的河道带的发育,以及植被维护的河岸使得河间湿地群体得以较长时间保存。     

黄河青藏高原网状河段不同流量下活动河道的分布规律

以黄河青藏高原阿万仓和采日玛两段主河道50 km与65 km长的网状河段为研究对象,利用2013年3期遥感影像绘制了不同流量下（176 m³/s,978 m³/s,1 610 m³/s）网状河段活动河道的分布变化图,结合DEM数据分析了现有河道在流量增加过程中的空间分布格局和潜在定量关系。研究结果表明：根据流量大小划分出的3类活动河道,其分布规律基本是后者位于前者的两侧,据此可以推断,网状河分支河道基本是从主河道向两侧逐渐发展的。对于阿万仓河段,在河谷和河间地相对宽阔处,每个河道断面上3类活动河道数的比值为1:1.67:2.25;而在河谷较窄的地方,该比值为1:1.22:1.33。在采日玛河段,该比值分别为1:1.3:1.4和1:0.95:1.16。在宽阔的草原湿地河段,当网状河的主河道发生弯曲时,弯道内侧的活动河道数要大于弯道外侧的活动河道数。在平坦开阔的河谷地带,断面上的活动河道线密度与河谷宽度之间呈现出极好的线性负相关关系;而峡谷地带由于两侧高地形的限制,河谷宽窄不一,活动河道的线密度相对较大、且差别也较大。     

赣江入湖三角洲上的网状河流体系研究

中国南方的冲积河流有许多属于分汊河流，这已被许多研究者进行过比较深入的分析研究，但赣江在其入湖三角洲上的多河道体系与分汊河道有着明显的不同，它的形成是河流自发调整的结果，而不象分汊河流那样由节点控制。它具有网状河流所具有的地貌和沉积物特征，属于典型的网状河流体系。虽然是低含沙河流，但由于其水动力较弱及汛期基准面的上升，洪泛频繁，可输入河间地以大量的泥沙并在低能环境中发生沉积，使河道及河间地能够协调加积升高，并维持多河道体系的稳定性。     

张家界甘溪砾石沉积物粒度的空间变化及其原因

以往研究沉积物粒度分布规律时,主要局限于砂质沉积物,至多涉及细砾,对于卵砾、卵石、漂石等粗大砾石沉积物的粒度分布规律很少涉及。以张家界山地河流甘溪现代砾石沉积物为研究对象,样品的颗粒粒径介于23~663 mm,分析了河床、心滩和河岸沉积物样品的累积频率分布曲线。结果表明,这些河流砾石沉积物具有较好的统计规律和空间变化趋势,其分布特征可以用累积频率曲线来表达,一般呈现出清晰的两段式或三段式分布特征,是对不同水位洪水动力的响应。粒度参数反映出这些砾石沉积物具有较好的分选性和球度。河道砾石的中值粒径沿程变小,反映了河流水动力沿程变小的规律。岩壁崩塌的砂岩块体短期难以受到流水的充分改造,使河流沉积物的峰态呈现多样化;漂石及卵石缝隙间拦截了低水位洪水所携带的部分较细砾石,引起河道砾石沉积物呈现负偏。该项研究对于山地河流巨大碎屑沉积物的定量研究具有启示作用。     

网状河流多重河道形成过程的实验模拟

网状河流是受到人们关注的新型冲积河流,其水文特征、地貌特征和沉积特征已经不同程度地被揭示。然而,网状河流的水槽实验迄今仍是空白,而水槽模拟实验是在时间和空间都大大缩小之后的自然界河流演变过程的再现。本文报道的是在实验水槽中通过原河道决口后网状河流的发生和演变过程。实验初始条件为:水槽辅助区的待决口河道,目标区为轴部略微下凹的长方形泛滥平原(4.5 m×16.5 m),其上下层分别为1.5 cm厚、中值粒径为0.0132 mm的高岭土层和0.5 m厚、中值粒径为0.188mm的天然细砂层,从5.5 m-17 m区段的平均纵比降为0.0058,17m-22m区段的平均纵比降为0.0077。采用的定常流量为3 L/s,悬移质输沙量在前3小时为4.5g/min,其后为1.2 g/s。实验总历时50小时。实验初期,目标区的上游段以垂向加积作用为主,中游以随机侵蚀为主,下游以溯源侵蚀为主,在13.5小时左右,相互连通的多重河道的网状河流体系的雏形基本展现。此后至25.5小时,网状河道的演变以下蚀为主演变为以适度的侧蚀,但河岸的后退幅度很小,标志网状河道逐步过渡到成熟期。从25.5小时至50小时,个别河道的局部废弃和决口是该成熟期网状河道演变的新特点。实验成功地模拟了天然网状河流的形成、发展和演变过程,同时也证明了它是不同于分汉河流的河型。这不     

塔里木河中游河段水文要素分析——以乌斯满河口上下游河段为例

采取工程措施调整干流上、中、下游区水量泄放比例,完成塔里木河流域综合治理工程项目,实现塔里木河的综合治理生态河流目标。由于中游河道比降小、砂质河岸极易侵蚀,河床宽浅,河道行洪能力低下;该段是塔里木河冲积平原南北伸展最宽的地段,是塔里木河河道泛滥地段,洪水使河道改道频繁。为进一步论证塔里木河中游河段控制型拦河枢纽工程对上下游河段堤防和两岸生态闸的影响,进行塔里木河中游拟建枢纽工程上下游河段内的水文要素观测、测量实验分析,掌握河段各项水文要素变化特征,分析河段内洪水的水面线、糙率的变化情况和中游河段的年径流量、最大洪峰流量、泥沙含量、输沙量等水文要素衰减率,以及河道内断面冲淤变化等问题,是为进一步研究洪水冲刷对堤防、水利工程影响的基本资料,是流域综合治理工程项目论证工作的必要条件。     

基于对Leopold-Wolman关系修正的河床河型判别

在广泛收集中国和世界上冲积河流资料的基础上,以近200条河流的大样本对著名的、国际上沿用40余年的 Leopold-Wolman关系,即用于河型判别的比降-流量关系进行了检验。结果发现,该关系不能用于包括砾石与砂质河床在内的河型判别。这是由于比降-流量关系主要反映砾石河床与砂质河床之间差异,其次才反映分汊与弯曲河型之间的差异。为此,对于Leopold-Wolman关系进行了改进,提出了以比降和河宽来判别河型的新关系。这一关系综合反映了河流在纵向上的能耗、阻力与输沙特性与在横向上的流场与环流分布特性的组合关系,因而具有更好的河型判别效果,可以用于包括砾石与砂质河床在内的河型判别。     

1966—2019年黄河乌兰布和沙漠宽谷段河道深泓横向摆动特征北大核心CSCD

受风沙入黄影响,黄河沙漠宽谷段河流地貌过程复杂,河道深泓摆动响应敏感。以1966—2019年黄河乌兰布和沙漠段河道断面为基础,提取深泓摆动参数,分析沙漠河流深泓横向摆动特征与规律,以期为沙漠河流管理提供参考。结果表明:河道深泓横向摆动强度与径流量及其年内分配不均匀系数、河床质粒度和河岸风沙动力条件呈现显著正相关;1966—2019年,河道深泓横向摆动幅度以每年8.24 m的速度下降,且波动幅度明显减小。河道深泓摆动过程中存在19 a和7 a时间尺度下的周期变化规律,摆动周期分别为13 a和5 a,且周期性不断减弱。深泓摆动速度与周期变化趋势指示沙漠宽谷辫状河道横向冲淤趋于稳定。     

1977年以来黄河临河段河岸冲淤变化及河道萎缩速率

不同时段河道的侧向侵蚀/加积面积变化的定量研究可以揭示河道的变化特征。以黄河临河段213 km长的河段为研究对象,利用1977年以来19个时段基于遥感影像绘制的河道平面形态图的面积变化来估算其4个亚河段（S1、S2、S3和S4）在不同时段的河岸侧向侵蚀/加积面积以及全河段的河道平均萎缩速率。研究结果表明,黄河临河段左右河岸在37年间都表现为侧向净加积,其4个亚河段左岸的侧向累计加积面积分别为33.16 km²、49.59 km²、29.52 km²和30.85 km²,其中1995-2000年的加积面积分别占到其总加积面积的85.5%、51.2%、47.2%和104.6%;右岸的侧向累计加积面积分别为30.83 km²、8.74 km²、26.44 km²和18.76 km²,而1995-2000年的加积面积分别占到其总加积面积的57.2%、111.9%、65.7%和61.6%。该河段河道面积1977-2001年具有减小趋势,2001年之后河道表现为侧向侵蚀、加积的交替变化,1977-2014年间河道平均萎缩速率为6.16 km²/yr。该河段河道平面形态值最明显的变化也发生在1990s,与1995年相比,2000年的河道长度增加了5.8%,河道面积减少了39.4%,河道平均宽度减小了42.8%,弯曲系数增加了6.6%。黄河临河段河道形态剧烈变化及河道严重萎缩都发生在1990s,这主要是黄河上游刘家峡和龙羊峡水库联合运行导致汛期水沙量大量减小所致,4个亚河段的河岸冲淤变化还受到局部河岸物质结构、护岸工程及水动力差异的影响。随着2000年后河流综合管理措施的调整,黄河临河段河道的上述变化趋势明显弱化,河流健康程度有所好转。     

河岸湿地研究的理论与应用技术

作为水陆之间的过渡带与生态交错区,河岸湿地具有一系列独特的性质和多种生态服务功能。鉴于河岸湿地在流域规划、河流保护与管理中的重要地位和作用,河岸湿地生态学研究已经开始得到重视。中国学者对河岸湿地生态学研究历经十余载,取得了众多研究成果,但是到目前为止,还没有形成一套比较系统和完备的学科体系,因而迫切需要加强该领域的系统研究工作。简要介绍了国内外河岸湿地基础理论,包括河岸湿地的定义、边界、结构和功能及其机理的研究;以及河岸湿地应用技术,主要包括河岸湿地生态模型与GIS技术的运用、岸坡稳定的生物工程技术和河岸湿地生态恢复的理论与实践等,提出了适应学科发展需要,综合已有的研究成果,构建河岸湿地生态学理论框架和学科体系的设想,以期推动河岸湿地生态学研究的发展。     

Planform characteristics and development of interchannel wetlands in a gravel-bed anastomosing river,Maqu Reach of the Upper Yellow River

Both interchannel wetlands and multi-channels are crucial geomorphologic units in an anastomosing river system. Planform characteristics and development of interchannel wetlands and multi-channels control the characteristics of anastomosing rivers. To understand the role that interchannel wetlands play in the development of anastomosing rivers, a study was conducted on the Maqu Reach of the Upper Yellow River (MRUYR), a gravel-bed anastomosing river characterized by highly developed interchannel wetlands and anabranches. Geomorphologic units in the studied reach were extracted from high resolution satellite imagery in Google Earth. The size distributions of interchannel wetlands and interchannel wetland clusters (IWCs), a special combination of interchannel wetlands and anabranches, were investigated. Geomorphologic parameters, including the ratio of interchannel wetland area to IWC area (P), shoreline density (D_l), and node density (D_n) were used to analyze planform characteristics of IWCs and the development of multi-channels in the studied reach. The results suggest that small or middle sized interchannel wetlands and large or mega sized IWCs are more common at the study site. The area of IWC (S_u) is highly correlated with other geomorphologic parameters. P increases with increasing S_u, and the upper limit is about 80%, which indicates that the development of interchannel wetlands and anabranches in the IWC is in the equilibrium stage. In contrast, D_l and D_n show a tendency to decrease with increasing S_u due to diverse evolution processes in IWCs with different sizes. There are three main reasons leading to the formation of IWCs: varying stream power due to the meandering principal channel; development of the river corridor due to the weakening of geologic structure control; and high stability of interchannel wetlands due to conservation by shoreline vegetation.     

黄河第一湾齐哈玛河段砾质网状河1990年以来的演变特征（英文）

The anastomosing river that is present within the First Great Bend of the Yellow River is different from other sand-bedded rivers of this type because it contains gravel-bedded materials. It is therefore important to determine whether, or not, the specific characteristics of this anastomosing river are similar to those seen in sand-bedded forms, including the characteristics of erosion and deposition, and the stability of channel and interchannel wetlands. Four Landsat images from 1990, 2001, 2013, and 2016 alongside two Google Earth(GE) images from 2011 and 2013 were utilized in this study in tandem with field sampling and observations to select a 12 km main channel length section of the Qihama reach anastomosing river. This section was then used to determine variations in channel planform and sedimentary characteristics over a 26 year period. The results of this study show that this gravel-bedded anastomosing river has exhibited a high degree of stability overall, and that there has been no obvious channel and wetland bank erosion and deposition. Data also show that over the 26 years of this study, anastomosing belt area increased by 2.43%, while the ratio of land to water area remained almost equal. The number of wetlands has also increased along this river section at a rate as high as 62.16% because of the fragmentation of some small interchannel examples, while the talweg has alternately migrated to either the left or right over long periods of time at a relatively stable rate. Indeed, as a result of the migration of this line, there has been significant turnover in the number of islands within the main channel while bank shift has occurred at a rate of about 5 m/yr. The numerous anastomosing channels within this river section remained very stable over the course of this study, characterized by a mean annual migration rate of just 1 m/yr, while the sediments in bank columnar sections are mainly composed of fine sands or silts with a relatively high clay content. The sediment grain-size distribution curve for this river section contains multiple peaks, distinct from the muddy sediments within bank columnar sections from sand-bedded anastomosing rivers. The dense vegetation within riparian and interchannel wetlands alongside this river reach has also protected anastomosing channels from erosion and maintainedtheir stability, a key feature of this gravel-bedded system.     

黄河玛曲砾质网状河段河间湿地形态特征及发育程度（英文）

Both interchannel wetlands and multi-channels are crucial geomorphologic units in an anastomosing river system. Planform characteristics and development of interchannel wetlands and multi-channels control the characteristics of anastomosing rivers. To understand the role that interchannel wetlands play in the development of anastomosing rivers, a study was conducted on the Maqu Reach of the Upper Yellow River(MRUYR), a gravel-bed anastomosing river characterized by highly developed interchannel wetlands and anabranches. Geomorphologic units in the studied reach were extracted from high resolution satellite imagery in Google Earth. The size distributions of interchannel wetlands and interchannel wetland clusters(IWCs), a special combination of interchannel wetlands and anabranches, were investigated. Geomorphologic parameters, including the ratio of interchannel wetland area to IWC area(P), shoreline density(D_l), and node density(D_n) were used to analyze planform characteristics of IWCs and the development of multi-channels in the studied reach. The results suggest that small or middle sized interchannel wetlands and large or mega sized IWCs are more common at the study site. The area of IWC(S_u) is highly correlated with other geomorphologic parameters. P increases with increasing S_u, and the upper limit is about 80%, which indicates that the development of interchannel wetlands and anabranches in the IWC is in the equilibrium stage. In contrast, D_l and D_n show a tendency to decrease with increasing S u due to diverse evolution processes in IWCs with different sizes. There are three main reasons leading to the formation of IWCs: varying stream power due to the meandering principal channel; development of the river corridor due to the weakening of geologic structure control; and high stability of interchannel wetlands due to conservation by shoreline vegetation.     

网状河流研究进展述评

网状河流作为一种新的冲积河流类型已经引起地貌学家、水利学家和沉积学家的关注 ,成为河流地貌领域、河流沉积领域以及河流水动力领域的研究热点之一。本文在介绍网状河流基本概念的基础上 ,综合国内外的研究成果 ,从河流的平面形态、边界条件、沉积特征、水动力条件以及在河型演化序列中的位置等方面 ,对网状河流的研究进展作一较全面的述评 ,并指出目前研究的薄弱环节 ,以利于研究者把握网状河流的研究现状 ,并推动对网状河流的进一步探讨。     

黄河流域河型转化现象初探

黄河以其高含沙水流以及下游河道的高沉积速率而著称于世。迄今的研究, 主要针对黄河中下游流域的 侵蚀、水文泥沙和河床演变方面的研究, 而对黄河流域主支流发生河型转化的现象关注不够。在黄河的不同河段, 河型的变化频繁, 类型多样, 现象复杂, 是研究者不可回避的科学问题。本文选取黄河上游第一弯的玛曲河段、黄河 上游末段托克托附近河段及黄河下游高村上下河段来研究河型转化的形式及影响因素。玛曲河段沿流向发生网状 河型→弯曲河型→辫状河型的转化现象, 该系列转化呈现出由极稳定河型向极不稳定河型的转化, 这与世界上通 常可以观察到的沿流向不稳定河型向稳定河型转化的情况完全相反。这主要受到地壳的抬升、上下峡谷卡口、水动 力特征、边界沉积物特征及植被的区域分布等因素的控制。托克托附近沿流向发生了弯曲河型→顺直河型转化的 现象, 这是较稳定河型向极稳定河型的转化, 主要受到边界沉积物、水动力等因素的控制。高村上下河段沿流向发 生的辫状河型→弯曲河型转化的现象, 是由极不稳定河型向较稳定河型转化的现象, 河道边界沉积物及水动力是 其主要控制因素, 人工大堤只是限制了河道摆动的最大幅度, 对河型的性质影响不大, 但其上游河段修筑的水库导 致下泻的水流在辫状河段的侵蚀能力增强而使其边界沉积物粗化, 并将泥质物大量沉积在弯曲河段, 客观上促进 了河型的转化。     

网状河流体系的基本特征及其影响因素

网状河流近年来受到较多关注,无论从沉积特征还是从地貌及水力学特征看,网状河流都是一种典型的河型,但目前对网状河流的认识还存在一定的局限性,从沉积特征,地貌及沉积微环境特征及形成条件等方面的对网状河流进行了系统的论述和总结。     

Reconstruction of anastomosing river course by means of geophysical and remote sensing surveys (the Middle Obra Valley,western Poland)

Intensive hydro technical works were conducted in the middle course of the Obra River (Poland) at the beginning of the nineteenth century. The ‘natural’ river course (functioning before the major construction works) was transformed into three artificial canals. Ground‐penetrating radar investigations, ground‐truthed with coring and remote sensing surveys, were conducted to reconstruct the course taken by the river prior to the hydro technical works. This work demonstrated that the Obra formerly had an anastomosing planform. Radiocarbon dating indicated that the earliest of the retraced channels were active before 9000 bp . The retraced river system was formed in a proglacial stream valley perpendicularly cut by remains of subglacial tunnels, now partly filled with lakes. The planform consisted of one or two major channels and a number of secondary channels formed by avulsions. During the last 2000 years, some of the avulsions may have been caused by anthropogenic interventions. The sequences of channel fill deposits indicate that particular channels changed from major to secondary ones. Sand deposits filling the bottom and middle parts of the channels point to an important role of upstream sediment supply causing in‐channel aggradation triggering the avulsions. Moreover, spatial variability in river patterns was found within the anastomosing system. Valley sections with meandering anabranches, anastomosing patterns with traces of a lateral migration and traces of a transition from meandering to anastomosing planform were distinguished.