Channel adjustments in response to the operation of large dams: The upper reach of the lower Yellow River

Ma, Yao; Huang, He Qing; Nanson, Gerald C.; Li, Yongi; Yao, Wei

doi:10.1016/j.geomorph.2011.07.032

Cited by 114 publications

(74 citation statements)

References 64 publications

(95 reference statements)

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“…1a). Although the Sanmenxia Reservoir initially had a volume of 36 billion m 3 , heavy sedimentation after its construction has reduced its available volume to less than 1 billion m 3 (Chen et al, 2002;Ma et al, 2012). Despite such a substantial loss, it still has some capacity for adjusting runoff and sediment, and the joint operation of these three large dams has successfully ended more than two decades of no-flows in the lower Yellow River and the YRD (e.g.…”

Section: Water Regulation Programmentioning

confidence: 99%

“…Wang et al, 2010;Chen et al, 2012;Chu, 2014). Due to the heavy deposition of sediment, the channel bed of the lower reach has become elevated above the adjacent valley floor by some 8 to 12 m over the past 40 years, so this water-sediment modulated scheme helps to reduce the discrepancy in channel and ground elevation (Ma et al, 2012;Chu, 2014).…”

Section: Water Regulation Programmentioning

confidence: 99%

“…The average annual runoff and sediment supply are the highest in the first period (1950)(1951)(1952)(1953)(1954)(1955)(1956)(1957)(1958)(1959)(1960)(1961)(1962)(1963)(1964)(1965) when the river adopted the Shenxiangou course, 61.5% and 64.1% higher than the corresponding averages for the entire 64 years (30.5 billion m 3 yr − 1 and 0.71 billion t yr −1 ), respectively. In the period [1966][1967][1968][1969][1970][1971][1972][1973][1974][1975] patterns of runoff and sediment load are closely linked to the operation of the four large reservoirs in the upper and middle reaches of the Yellow River, as detailed by Ma et al (2012) and Chu (2014).…”

Section: Changing Patterns Of Water and Sediment Supply To The Yrdmentioning

confidence: 99%

“…Consequently, the amount of water and sediment delivered to the YRD has reduced and the rate of sedimentation in the estuary slowed greatly, causing significant coastal erosion in many parts of the delta (e.g. Chu et al, 2006;Saito et al, 2007;Wang et al, 2010;Ma et al, 2012;Yu et al, 2013a,b;Chu, 2014;Liu et al, 2014;Zhou et al, 2014). The delta today supports a human population of more than two million who obtain their livelihood from farming, fishing and oilexploiting, so changes to its water and sediment supply and land area can have profound impacts.…”

Section: Introductionmentioning

confidence: 99%

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Progradation of the Yellow (Huanghe) River delta in response to the implementation of a basin-scale water regulation program

et al. 2015

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The water and sediment supply to the lower reach and estuary of the Yellow (Huanghe) River have been altered to a very significant degree by the construction of numerous small to large reservoirs and the progressive implementation of water and soil conservation measures across the entire drainage basin since the late 1950s, followed by a basin-scale water regulation program since 2002. There is an urgent need to know how progradation of the Yellow River delta (YRD), an area on which people live and farm, has continued and will continue to respond to these controls. This study examines the changing patterns of water and sediment supply to the YRD over the period of 1950-2013 and, using remote sensing, it evaluates the morphological changes of the delta during 1976-2013. Although both water and sediment input to the delta have been described as declining significantly since the mid 1960s, we show that since 2005 the supply of water has remained at around 20 billion m 3 yr −1 and that for sediment at about 0.13 billion t yr −1 ; water input has been even slightly increasing. The dynamics of extension/shrinking and avulsion in river-mouth channels and accretion/erosion of shorelines is an integrated response to the complex variations in both sediment and water supply. This study develops a quantitative relationship between water and sediment supply and the area of land accretion and it predicts the critical condition for land accretion in the YRD. To ensure that delta land will not be lost, care is needed in the future implementation of the basin-scale water regulation program.

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Section: Water Regulation Programmentioning

confidence: 99%

Section: Water Regulation Programmentioning

confidence: 99%

Section: Changing Patterns Of Water and Sediment Supply To The Yrdmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Progradation of the Yellow (Huanghe) River delta in response to the implementation of a basin-scale water regulation program

et al. 2015

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“…The river channel bed is composed of fine sand (mean grain size b 0.1 mm; Table 2). The high suspended sediment load in the lower Yellow River exerts great influence on channel morphology change (Qian and Zhou, 1965;Wang et al, 2009b;Ma et al, 2012). Although some investigations have studied flow resistance in the lower Yellow River (Qian et al, 1959;Qian and Zhou, 1965;Qin et al, 1995;Cheng et al, 1997;Sun et al, 2005), a clear recognition of the major controls on flow resistance is still lacking.…”

Section: Introductionmentioning

confidence: 99%

Controls of channel morphology and sediment concentration on flow resistance in a large sand-bed river: A case study of the lower Yellow River

Huang

2016

Geomorphology

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Accurate estimation of flow resistance is crucial for flood routing, flow discharge and velocity estimation, and engineering design. Various empirical and semiempirical flow resistance models have been developed during the past century; however, a universal flow resistance model for varying types of rivers has remained difficult to be achieved to date. In this study, hydrometric data sets from six stations in the lower Yellow River during 1958-1959 are used to calibrate three empirical flow resistance models (Eqs. (5)- (7)) and evaluate their predictability. A group of statistical measures have been used to evaluate the goodness of fit of these models, including root mean square error (RMSE), coefficient of determination (CD), the Nash coefficient (NA), mean relative error (MRE), mean symmetry error (MSE), percentage of data with a relative error ≤ 50% and 25% (P 50 , P 25 ), and percentage of data with overestimated error (POE). Three model selection criterions are also employed to assess the model predictability: Akaike information criterion (AIC), Bayesian information criterion (BIC), and a modified model selection criterion (MSC). The results show that mean flow depth (d) and water surface slope (S) can only explain a small proportion of variance in flow resistance. When channel width (w) and suspended sediment concentration (SSC) are involved, the new model (7) achieves a better performance than the previous ones. The MRE of model (7) is generally b 20%, which is apparently better than that reported by previous studies. This model is validated using the data sets from the corresponding stations during [1965][1966], and the results show larger uncertainties than the calibrating model. This probably resulted from the temporal shift of dominant controls caused by channel change resulting from varying flow regime. With the advancements of earth observation techniques, information about channel width, mean flow depth, and suspended sediment concentration can be effectively extracted from multisource satellite images. We expect that the empirical methods developed in this study can be used as an effective surrogate in estimation of flow resistance in the large sand-bed rivers like the lower Yellow River.

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Sustainable sediment management in reservoirs and regulated rivers: Experiences from five continents

Gao²,

et al. 2014

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By trapping sediment in reservoirs, dams interrupt the continuity of sediment transport through rivers, resulting in loss of reservoir storage and reduced usable life, and depriving downstream reaches of sediments essential for channel form and aquatic habitats. With the acceleration of new dam construction globally, these impacts are increasingly widespread. There are proven techniques to pass sediment through or around reservoirs, to preserve reservoir capacity and to minimize downstream impacts, but they are not applied in many situations where they would be effective. This paper summarizes collective experience from five continents in managing reservoir sediments and mitigating downstream sediment starvation. Where geometry is favorable it is often possible to bypass sediment around the reservoir, which avoids reservoir sedimentation and supplies sediment to downstream reaches with rates and timing similar to pre-dam conditions. Sluicing (or drawdown routing) permits sediment to be transported through the reservoir rapidly to avoid sedimentation during high flows; it requires relatively large capacity outlets. Drawdown flushing involves scouring and re-suspending sediment deposited in the reservoir and transporting it downstream through low-level gates in the dam; it works best in narrow reservoirs with steep longitudinal gradients and with flow velocities maintained above the threshold to transport sediment. Turbidity currents can often be vented through the dam, with the advantage that the reservoir need not be drawn down to pass sediment. In planning dams, we recommend that these sediment management approaches be utilized where possible to sustain reservoir capacity and minimize environmental impacts of dams.

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Channel adjustments in response to the operation of large dams: The upper reach of the lower Yellow River

Cited by 114 publications

References 64 publications

Progradation of the Yellow (Huanghe) River delta in response to the implementation of a basin-scale water regulation program

Progradation of the Yellow (Huanghe) River delta in response to the implementation of a basin-scale water regulation program

Controls of channel morphology and sediment concentration on flow resistance in a large sand-bed river: A case study of the lower Yellow River

Sustainable sediment management in reservoirs and regulated rivers: Experiences from five continents

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