Coupled 1D–3D hydrodynamic modelling, with application to the Pearl River Delta

Twigt, Daniel; Goede, E.D. de; Zijl, Firmijn; Schwanenberg, Dirk; Chiu, Alex Y. W.

doi:10.1007/s10236-009-0229-y

Cited by 39 publications

(18 citation statements)

References 16 publications

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“…Numerical models simulating hydrodynamics, sediment transport, and morphodynamics are in a phase of rapid developments toward generic tools that may address the needs in the context of tidal wetland restoration and taking measures to cope with climate change. Flexible meshes accommodate the land‐sea continuum in models stretching from deep water (>100 m) up until the upstream limit of the tidal river [e.g., Hervouet , ; Twigt et al , ; de Brye et al , ; Canestrelli et al , ; de Brye et al , ]. Resolution flexibility captures the multiscale nature of the nonlinear development of a tidal wave propagating from deep water into a tidal river.…”

Section: Implications For Deltasmentioning

confidence: 99%

Tidal river dynamics: Implications for deltas

Hoitink

Jay

2016

Reviews of Geophysics

277

226

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Tidal rivers are a vital and little studied nexus between physical oceanography and hydrology.It is only in the last few decades that substantial research efforts have been focused on the interactions of river discharge with tidal waves and storm surges into regions beyond the limit of salinity intrusion, a realm that can extend inland hundreds of kilometers. One key phenomenon resulting from this interaction is the emergence of large fortnightly tides, which are forced long waves with amplitudes that may increase beyond the point where astronomical tides have become extinct. These can be larger than the linear tide itself at more landward locations, and they greatly influence tidal river water levels and wetland inundation. Exploration of the spectral redistribution and attenuation of tidal energy in rivers has led to new appreciation of a wide range of consequences for fluvial and coastal sedimentology, delta evolution, wetland conservation, and salinity intrusion under the influence of sea level rise and delta subsidence. Modern research aims at unifying traditional harmonic tidal analysis, nonparametric regression techniques, and the existing understanding of tidal hydrodynamics to better predict and model tidal river dynamics both in single-thread channels and in branching channel networks. In this context, this review summarizes results from field observations and modeling studies set in tidal river environments as diverse as the Amazon in Brazil, the Columbia, Fraser and Saint Lawrence in North America, the Yangtze and Pearl in China, and the Berau and Mahakam in Indonesia. A description of state-of-the-art methods for a comprehensive analysis of water levels, wave propagation, discharges, and inundation extent in tidal rivers is provided. Implications for lowland river deltas are also discussed in terms of sedimentary deposits, channel bifurcation, avulsion, and salinity intrusion, addressing contemporary research challenges.

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Section: Implications For Deltasmentioning

confidence: 99%

Tidal river dynamics: Implications for deltas

Hoitink

Jay

2016

Reviews of Geophysics

277

226

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“…There are also studies combining 1D SOBEK (river areas) with Delft 3D (coastal zones) to simulate the hydrodynamic of river estuaries. With this approach, Lam et al [26] study the zone of Thuan An (Vietnan) and Twigt et al [27] study river Pearl Delta (Guangdong, China).…”

Section: Sobek 1dmentioning

confidence: 99%

A Review of Software Tools to Study the Energetic Potential of Tidal Currents

et al. 2019

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Tides can be a vast and predictable source of renewable energy. Due to the solar and lunar influx on our planet, they move large amounts of water periodically, and this energy can be harnessed using devices designed and positioned adequately, such as current turbines. However, the relation between the energy obtained with actual devices and the economic and environmental cost of their installation limits the practical application of these solutions. In order to optimize the design of this technology and achieve its successful installation and use, a detailed knowledge about the energy potential of tides at the specific location is necessary. This calculation is not easy and requires the use of specialized software tools. Currently, there is no specific software to evaluate the tidal currents energy potential, but there are more than a few codes able to calculate the hydraulic flow in rivers, estuaries and coastal regions. These programs are usually used for the calculation of pollutant dispersion and floods, but they can be adapted with more or less success. This paper reviews the available 1D, 2D, and 3D software tools with the aim of analyzing their functionality and their validity to evaluate the energy potential of tidal currents.

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“…The interactions among freshwater inflow, sediment discharge, nutrient transport, tides, winds, varying topography, large-scale circulations and rotating effect make the ZE a rather complicated system (Wong et al, 2003a(Wong et al, , b, 2004Dong et al, 2004;Mao et al, 2004;Larson et al, 2005;Yin and Harrison, 2007;Twigt et al, 2009;Ou et al, 2009;Ji et al, 2011;Zu et al, 2014;Zheng et al, 2014;Liu et al, 2015). And complicated hydrodynamic characteristics of the ZE draw great interest in the past few decades.…”

Section: Introductionmentioning

confidence: 97%

Tidal energy budget in the Zhujiang (Pearl River) Estuary

Bai

et al. 2016

Acta Oceanol. Sin.

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Tidal energy budget in the Zhujiang (Pearl River) Estuary (ZE) is evaluated by employing high-resolution baroclinic regional ocean modeling system (ROMS). The results obtained via applying the least square method on the model elevations are compared against the tidal harmonic constants at 18 tide stations along the ZE and its adjacent coast. The mean absolute errors between the simulation and the observation of M 2 , S 2 , K 1 and O 1 are 4.6, 2.8, 3.2 and 2.8 cm in amplitudes and 9.8°, 15.0°, 4.6° and 4.6° in phase-lags, respectively. The comparisons between the simulated and observed sea level heights at 11 tide gauge stations also suggest good model performance. The total tidal energy flux incoming the ZE is estimated to be 343.49 MW in the dry season and larger than 336.18 MW in the wet season, which should due to higher mean sea level height and heavier density in the dry season. M 2 , K 1 , S 2 , O 1 and N 2 , the top five barotropic tidal energy flux contributors for the ZE, import 242.23 (236.79), 52.97 (52.08), 24.49 (23.96), 16.22 (15.91) and 7.10 (6.97) MW energy flux into the ZE in dry (wet) season, successively and respectively. The enhanced turbulent mixing induced by eddies around isolated islands and sharp headlands dominated by bottom friction, interaction between tidal currents and sill topography or constricted narrow waterways together account for the five energy dissipation hotspots, which add up to about 38% of the total energy dissipation inside the ZE.

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Coupled 1D–3D hydrodynamic modelling, with application to the Pearl River Delta

Cited by 39 publications

References 16 publications

Tidal river dynamics: Implications for deltas

Tidal river dynamics: Implications for deltas

A Review of Software Tools to Study the Energetic Potential of Tidal Currents

Tidal energy budget in the Zhujiang (Pearl River) Estuary

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