Microsoft Word - 12-3506_s_ETASR_V10_N3_pp5648-5654

Engineering, Technology & Applied Science Research Vol. 10, No. 3, 2020, 5648-5654 5648

www.etasr.com Cham et al.: Hydrodynamic Condition Modeling along the North-Central Coast of Vietnam

Hydrodynamic Condition Modeling along the North-

Central Coast of Vietnam

Dao Dinh Cham

Institute of Geography
Vietnam Academy of Science and

Technology

Hanoi, Vietnam
chamvdl@gmail.com

Nguyen Thai Son

Institute of Geography
Vietnam Academy of Science and

Technology

Hanoi, Vietnam
nguyenthaison99@gmail.com

Nguyen Quang Minh

Institute of Geography
Vietnam Academy of Science and

Technology

Hanoi, Vietnam
nguyenquangminh2110@gmail.com

Nguyen Thanh Hung

Key Laboratory for River and Coastal Engineering
Vietnam Academy for Water Resources

Hanoi, Vietnam

nthungpacific@gmail.com

Nguyen Tien Thanh

Dpt. of Hydrometeorological Modeling and Forecasting
Thuyloi University

Hanoi, Vietnam

thanhnt@tlu.edu.vn

Abstract—An extremely dynamic morphology of the estuary is

observed in the coastal regions of Vietnam under the governing

processes of tides, waves, and river system flows. The primary

target of this paper is to provide insight into the governing

processes and morphological behavior of the Nhat Le estuary,

located in the north-central coast of Vietnam. Based on measured
data from field surveys and satellite images combined with

numerical model simulations of MIKE and Delft3D, the

influences of seasonal river flow, tides, and wave dynamics on the

sediment transport and morphological changes are fully

examined. The study showed that freshwater flow in the flood

season plays a central role in cutting off the southern sandspit,
maintain and shaping the main channel. The prevailing waves in

winter and summer induce longshore drift and sediment

transport in the southeast to northwest direction. In the low flow

season, this longshore sediment transport is dominant, causing

sediment to deposit on the southern side of the ebb tidal delta and

elongating the southern sandspit which narrows the estuary
entrance and reorients the main channel.

Keywords-hydrodynamics; morphology; Delft3D; Nhat Le

estuary; MIKE

I. INTRODUCTION

Coastal and estuarial morphological features highly depend
on the combined influence and interplay of river flows, waves,
tides, and currents. Additionally, meteorological phenomena
significantly affect the hydrodynamic and morphodynamic
processes of estuarial and coastal zones [1]. Especially in the
tropics, the effects of atmospheric circulations on a synoptic
scale on the precipitation regime and changes in temperature
are carefully monitored [2-3]. The behavior of hydrologic
processes is analyzed by hydrological models [4]. Generally,
these studies illustrate changes in river flows and evolutions of
estuarial or oceanic features dominated by the effects of
atmospheric circulations. The effects of dam construction on

the morphology are investigated in [5]. Authors in [6] used the
Deflt3D system [5] to study the fluvial erosion and to
investigate the temporal evolutions of hydrodynamic processes.
This system is widely applied in researches in hydrodynamics,
sediment transport and wave modeling [8-12]. Interaction of
wave-current and tidal depth changes are considered in Katama
Bay using combined models of Deflt3D-FLOW and SWAN.
These studies indicated a good reproduction of waves and
currents. These studies mostly emphasize on the regions
dominated by physical processes at a large scale. For many
projects dealing with water resources and hydrodynamics,
MIKE system [13] is applied [14-17]. The uncertainty strongly
depends on a large range of data requirements and parameter
values [18]. In other words, there is a need to further
investigate the performance of MIKE for the estuary and
coastal areas in the tropics like Vietnam where the dynamics
are very unstable. In the coastal zones of Vietnam, human
activities and natural environment changes lead to imbalance in
the coastal processes, changes in dynamical action, and
sediment transfer. So far, only a small number of studies have
been conducted in this topic [19-20].

The Nhat Le estuary is selected as a study area, along the
north-central coast of Vietnam. It is located in Quang Binh
province as shown in Figure 1. It connects a drainage basin of
2647km

2
to the Gulf of Tonkin. Under the governance of wave

and river hydrodynamics in a tropical monsoon region, the
morphology of the estuary and the adjacent coast are very
dynamic and unstable. During the last ten years, the
development of the southern sandspit posed difficulties for
navigation, especially for the fishing boats entering the shelter
areas during typhoons or rough sea conditions. Since 1977, the
northern and southern coasts have been eroded by the alternate
attacks of the monsoon waves. Many research and dredging
projects have been invested and several coastal structures have
been built to stabilize the estuary, but the problems remain, due

Corresponding author: Nguyen Tien Thanh

Engineering, Technology & Applied Science Research Vol. 10, No. 3, 2020, 5648-5654 5649

www.etasr.com Cham et al.: Hydrodynamic Condition Modeling along the North-Central Coast of Vietnam

to the fact that the main governing processes and the actual
mechanism of the estuary’s morphological instabilities are still
not clearly understood. Therefore, the goad of this study is to
comprehend the changes in bed-sea topography and the causes
of estuary evolution, while additionally providing more insight
into the main governing processes and the behavior of the
morphology at the estuary based on measured data and
numerical modeling of hydrodynamics, sediment transport, and
morphological changes at the estuary.

Fig. 1. Study area (screenshot from Google Earth, map data: Esri, Digital

Globe, GeoEye, Earthstar Geographics, CNES/Airbus DS, USDA, USGS,

AeroGRID, IGN, and the GIS User Community)

II. THE STUDY AREA

The Nhat Le River is 85km long, origins from the Truong
Son Cordillera with two major tributaries, Dai Giang and Kien
Giang, and discharges into the sea at Dong Hoi city. Near the
estuary the river has a width of about 400 to 500m, an average
depth of 2 to 4.5m and a maximum depth of 7m. The river flow
regime is strongly governed by the tropical monsoon climate
regime with the two distinguish flood and dry seasons. The
flood season lasts from September to December when the
northeast monsoon winds carry moisture from the sea and
cause considerable rainfall and river floods. Also, torrential
rain may occur from July to October due to severe typhoons
coming from the Western Pacific basin. The flood season only
lasts four months but produces 76% of the annual flow. The
mean annual rainfall is about 2500mm. The dry season is
characterized by a dry and hot climate due to the sheltering of
the Truong Son Cordillera from the southwest monsoon winds.

The tidal regime in this area is semi-diurnal with a spring
tidal range of 1.2-1.6m. Due to the micro tidal regime, the tidal
currents are also weak. The observed tidal currents along the
coast are smaller than 0.5m/s. The wave climate strongly
reflects the monsoon system. In the northeast monsoon season
the prevailing wave direction is from Northeast, the average
wave height is 0.8-0.9m but the highest winter wave height can
be 4.0-4.5m. In the summer, the dominant wave directions are
Southwest and Southeast with an average wave height of 0.6-
0.7m while the highest wave height can reach 3.5–4.0m.
During major storms wave height may exceed heights of 6m.

III. MATERIALS AND METHODOLOGY

A. Materials

Instruments were used and installed at measurement
stations. Typically, the Trimble R8s is used to create a
topography on land [21]. JMCF-2000 and Odom Hydrotrac II
are used to create a topography of the seabed [22]. The primary
instrument used for wave data collection was the Nortek
Acoustic Wave and Current Profiler (AWAC) [23]. Field data
at the Nhat Le estuary have been measured intensively by the
authors themselves for projects of the Institute of Geography
(e.g. project with the code VAST 06.03/15-16) during the
period from 2005 to 2016. The data include bottom
topography, waves, tidal water level, river discharge, and
sediment grain sizes. Within this project, Dong Hoi hydrologic
station is newly installed to measure tidal water level and
discharge. The data include bottom topography, waves, tidal
water level, river discharge, and sediment grain sizes. Figure 2
shows the locations of stations including the Dong-Hoi
hydrological station and AWAC deployments to measure
waves.

B. Numerical Modeling: Set-up and Boundary Conditions

The MIKE is an implicit finite difference model for one
dimensional unsteady flow computation and can be applied to
simulate surface runoff, flow, sediment transport, estuaries,
water quality or floodplains [13]. For this study, MIKE 11HD
package was applied [13]. The upstream boundary conditions
include river flow discharge computed for 8 tributaries using
rainfall-runoff model (i.e. Nedbor - Astromnings - Model
(NAM)) [24] coupled with MIKE 11 [25]. The NAM model is
used as a module of MIKE 11 under the name of MIKE-NAM.
The output of NAM (i.e. discharge) is used as upper boundary
condition at 8 the tributaries for MIKE 11HD to compute the
hydraulic boundaries. The upper boundary locations are shown
in Figure 2. This model was originally developed by the
Department of Hydrodynamics and Water Resources at the
Technical University of Denmark [26]. It is a conceptual
model, describing the physical characteristics of the basin, on
the basis of which it calculates rainfall flows. The NAM is the
conceptual hydrological model. Its parameters and variables
present the mean values for the entire basin. The input data for
NAM include the time series data of rainfall at Kien Giang
hydrologic station (17°00'40.89"N, 106°44'09.94"E), time
series of daily mean air temperature, wind speed, relative
humidity, and solar radiation at Dong Hoi (Meteo)
(17°28'19.83"N, 106°37'27.32"E) to simulate daily
evaportranspiration, and flow discharge for the catchments.

The process-based numerical model system Delft3D [7]
primarily designed with a focus on applications of water flow
and quality, was applied in this study. The ocean forcings (i.e.
tidal, wave actions, and sediment transport) were simulated
using the Delft3D model, namely a couple of Delft3D-FLOW
and Delft3D-WAVE using SWAN [7, 27-28] were applied to
take into account the influences of tides, wave forcing, and
river discharges. The FLOW model is a hydrodynamic
component of Delft3D with a three dimensional hydrodynamic
and transport simulation program. It is applied to solve the
depth-averaged non-linear shallow water equations for non-
steady flows. Simulations of hydrodynamic, sediment transport

Engineering, Technology & Applied Science Research Vol. 10, No. 3, 2020, 5648-5654 5650

www.etasr.com Cham et al.: Hydrodynamic Condition Modeling along the North-Central Coast of Vietnam

changes were conducted. The WAVE model is also a
component of Delft3D with two available modules of HISWA
[29] and SWAN [27] as the second and third generation wave
model, respectively. In this study, SWAN model was applied
for wave propagation and transformation in near-shore.

Fig. 2. Computational domain and grid

The modules of RGFGRID and QUICKIN combined
within the Delft3D system were used to create smooth,
orthogonal curvilinear grids and interpolate the topographic
data. Figure 2 shows the model domain, computational grid,
bathymetry at the estuary and locations of upstream flow
boundaries and observation stations. The computational grid
for the Nhat Le estuary and its rivers and adjacent continental
shelf consists of 512×329 nodes. Fine-grid resolution was used
locally and coarse resolution was used away from the regions
of interest. The maximum grid size at the offshore open
boundary is about 300m. The depth is extended to -5m and
-52m for the near-shore and offshore areas respectively. The
grid areas are enlarged from about 3km up to about 40km for
the boundary of near-shore and offshore far from the coastline
respectively. Grid cells in the main estuary channels are 15m in
length, while grid cells in outer are up to 300m in length. The
bathymetry for the fine grid mesh is taken from survey at 30m
resolution in the Nhat Le estuary area and 500m resolution for
offshore areas. The seaward open boundary forcings were
assumed to be astronomical tides. Based on the global ocean
tide model TPXO 8.0 [30], ten tidal constituents of Q₁, O₁, P₁,
K₁, M₂, S₂, K₂, N₂, Mf, Mm were found to be dominant in the
area and were used as the open boundary conditions of the
model. Note that the boundary conditions of wave model are
deep-water wave parameters (i.e. significant wave height, peak
wave period, mean wave direction) from WAVEWATCH III
model [28]. For simulations of sediment transport, the
parameters automatically adopted from [8-9, 32-33] were used.

IV. RESULTS AND DISCUSSION

A. Results

At first the model performance of MIKE and Delft3D
system needs to be calibrated and validated. In the process of
calibration, model parameters were modified to reduce the

error between the simulated and observed discharges. The
model parameters found during model calibration were kept in
the process of validation. The measured flow data at Kien-
Giang station were used to validate the rainfall-runoff and river
flow model. Figure 3 shows the discharge simulations of MIKE
system for calibration and validation during the flood seasons
of 2015 and 2016. It is observed that the difference between
simulation and observation discharge at Kien Giang is
negligible with Nash-Sutcliffe indices [26] of 0.89 (in 2015)
and 0.98 (in 2016). It is significantly remarkable to provide
well-fitted results of models against the measured data as
shown in Figure 3 at Kien-Giang station. The model calibration
and validation showed that the timing of the peaks was
captured well, but the model slightly underestimated the
discharge value in November 2015 for calibration. The
parameters of overland flow runoff coefficient (CQOF) and
time constants for routing overland flow (CK12) are most
sensitive to the simulation results of discharge, followed by the
maximum water content in root zone storage (Lmax) and root
zone threshold value for overland flow (TOF) parameters.
These parameters are defined on the basis of statistical
performance indices (i.e. coefficient of determination).

(a)

(b)

Fig. 3. Comparison between modeled and observed flow discharges at

Kien-Giang station for the flood seasons in (a) 2015 and (b) 2016

The hydrodynamic model was calibrated for the period
from 16 May to 20 May 2015 using the collected data at the
AWAC station in the estuary. Model validation is firstly
performed using the water level, depth averaged current, and
wave measurements at the AWAC station. Figures 4-5 present
a comparison between model predictions and measurements for
water surface levels and depth averaged flow currents at
AWAC station. The Nash-Sutcliffe indices for the efficiencies
of the model versus data for water surface elevation, x- and y-
components of flow velocity are 0.96, 0.76 and 0.63
respectively indicating a good agreement between the model
and the data. The model output is mostly influenced by the
water level and discharge at the model boundaries and is
especially sensitive to winds. Besides water surface elevation
and depth averaged flow currents, the comparison of wave

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www.etasr.com Cham et al.: Hydrodynamic Condition Modeling along the North-Central Coast of Vietnam

parameters including significant wave height, wave period, and
wave direction between model and data also provides
reasonable agreement (Figure 6).The satellite images and field
survey data were used to validate the simulations of the
sediment transport.

Fig. 4. Modeled (blue) and measured (red) water level at AWAC station

(a)

(b)

Fig. 5. Comparison between modeled (blue) and measured (red) flow

velocities for (a) x- and (b) y- components at AWAC station

(a)

(b)

(c)

Fig. 6. Model prediction and measured data comparison for (a) significant

wave height, (b) wave period, and (c) wave direction at AWAC station

B. Discussion

Based on the calibrated model, hydrodynamics and
morphodynamics of the Nhat Le estuary were simulated and
analyzed to investigate the influences of different governing
processes such as tides, waves and river flows. Firstly, a
simulation of fresh water inflow and tides-only forcing was

carried out. Then a fully hydrodynamic model of all forcing
(fresh water inflow, tides, winds and waves) was simulated.
Two simulation periods, May 2015 and September 2015,
represented the different conditions in summer and winter
respectively.

1) Wave Characteristics

The model results of wave parameters were extracted at
four different locations (P1 to P4) surrounding the entrance
(Figure 7(a)). Wave roses for the period of 2015-2016 are
plotted for these locations in Figure 7(b). The purpose of this is
to clarify the role of winds in affecting the wave characteristics.
It is observed that the deep-water waves are prevailing from the
East and North-Northeast directions. When the waves are
approaching the estuary, the dominant wave directions are East
and Northeast due to wave refraction. As the Northeast waves
are mostly normal to the coastline, the wave action would
contribute mainly on the cross-shore sediment transport but not
the long-shore sediment transport. Therefore, the dominant
Eastern waves could be the major source in inducing long-
shore sediment transport in the estuary. Due to the dominant
Eastern wave actions, the net long-shore sediment transport is
directed in the Southeast-Northwest which elongates the
southern sandspit and forces the main channel to head North.

(a)

(b)

Fig. 7. Locations for wave extraction, (b) corresponding wave roses

2) Estuary Hydrodynamics

Figure 8 shows the peak velocities of ebb and flood tide
velocities in three different situations: 1) tidal only forcing, 2)
tides and Northeast waves in winter monsoon season, and 3)
tides and Southeast waves in summer monsoon season.
Snapshots of the depth-averaged currents during flood and ebb
tide periods show the strong velocities in the tidal channel at
the entrance due to the restriction of the entrance because of the
elongating southern sandspit. The combination of tides and
fresh water inflow causes much stronger ebb tidal velocity than

Engineering, Technology & Applied Science Research Vol. 10, No. 3, 2020, 5648-5654 5652

www.etasr.com Cham et al.: Hydrodynamic Condition Modeling along the North-Central Coast of Vietnam

flood tidal velocity (Figures 8(a) and 8(d)). The strongest flow
velocities during flood and ebb tides at the entrance have an
important role in maintaining the entrance and orienting the
main channel. Away from the entrance, the flow currents
decrease quickly over the ebb tidal delta. It can be seen that the
tidal currents along the coast during the ebb tide are much
stronger than during the flood tide, making the system to export
sediments to the southern coast, i.e. the tidal currents transport
fluvial sediment from the river mostly to the southern coast.

Fig. 8. Peak velocities during flood tide (top) and ebb tide (bottom) in

different tide and seasonal wave conditions (axes units are meters)

In the case of wave present, the contribution of wave
radiation stresses makes the flow field to be more complex.
The results show that the long shore currents during the winter
NE waves are much stronger than during the summer SE waves
but both wave conditions generate long shore currents and long
shore sediment transport in the SE-NW direction which cause
the southern sandspit to elongate Northwest. Unlike the fresh
water flow and tide only conditions, in the case of wave present
both flood and ebb currents seem stronger and the flood
currents are able to transport sediment from the ebb tidal delta
and those delivered by long shore currents further landward
thus reshaping the shores. The model results suggest that tidal
and river flows dominate the main channel and the inner
estuarine zone. Especially during high river discharge events,
which are frequent over winter months, river discharge and ebb
tides flush sediment seaward and then the offshore tidal
currents will transport the sediment to supply the southern
coast. Wave-induced circulations and alongshore currents
prevail on the ebb tidal delta and in the near-shore region on
both sides of the estuarine mouth. In the near-shore area away
from the inlet, wave-induced circulation patterns are often
driven by the interaction between the waves and the seabed.
The strong wave radiation stress modifies the pattern of the
depth-averaged velocity especially near to the coast and the

sand bar due to wave breaking in this region. Under the
condition of combined currents and waves, the flow magnitude
increases considerably in the tidal channel and particularly in
shallow water depths. It is specially noted that coastal waves
induced by currents (e.g. tidal currents) could reach up to
0.5m/s in most of the coastline. These currents combined with
tidal and river flow produce a jet that can reach the depth of
10m in ebb tide conditions.

3) Sediment Transport and Bottom Changes

Sediment transport and bottom morphological changes are
simulated for various conditions of hydrodynamic and wave
forcings. Sediment grain size is setup uniformly with
d50=0.03mm based on bed core data. Tides, waves, and river
discharge are the main parameters that effect on the sediment
transport and morphology responses.

(a)

(b)

(c)

Fig. 9. Erosion/accretion processes are displayed by (a) simulation

modeling, (b) Google Earth Image (Screenshot from Google Earth, Map data:

Image@2015 Digital Globe, Image@2015 TerraMetrics and Maxar
Technologies), and (c) survey data for the flood season in 2015

The simulations’ performance was well-fitted to the
measured data during the high flow season. It is observed that
sediment has pushed away from the estuary to the ebb tidal
delta (Figure 9). Alongshore wave-driven and tidal currents

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redistribute this sediment to accrete along the coastline. It is
worth noting that during the low flow season, as a result of the
long shore drift and sediment transport from the south which is
weakly interrupted by the tides and river inflow, sediment
continues to accumulate and deposit at the southern side of the
ebb tidal delta and at the tip of the southern sandspit and causes
the sandspit to develop northward (Figure 10).

(a)

(b)

Fig. 10. Erosion/accretion processes are displayed by (a) simulation

modeling and (b) survey data for a low flow season (2015)

V. CONCLUSIONS

This study presents the first attempt to fully couple
hydrodynamic and morphodynamic models (MIKE and
Delft3D) for a better insight into the morphology evolution of
Nhat Le estuary, Vietnam. The simulations document a series
of complexity trends under the ensemble effects of tides,
waves, flows, and winds. The major physical processes
governing the estuary morphology including tides, waves, and
freshwater discharge were simulated. The model system was
calibrated and validated using measured and observed data
from 2005 to 2016. The simulations presented in this paper are,
of course, limited to the particular sedimentary and
morphological conditions of the Nhat Le estuary. Although the
findings are not considered with sedimentary and geological
evolution at the upstream of Nhat Le river basin and at a
regional scale of north-central coast of Vietnam, they allow
making hypotheses and conducting further research in a wider
range. The results of the simulations are in accordance with the
measured and observed data during the periods of calibration
and validation. The results demonstrate that the seasonal
variations of freshwater flow and ocean waves under the
tropical monsoon regime significantly affect the behavior of the
estuary morphology. The role of freshwater flow in the flood
season is to cut off the southern sandspit, maintain, and shape
the main channel. Sediment from the river is exported to the
ebb tidal delta due to the ebb dominant freshwater inflow and
tidal currents. Outside the estuary, ebb dominant tidal currents

transport the sediment to the South and supply the southern
coast. The prevailing waves in winter and summer induce long
shore drift and sediment transport in the SE-NW direction. In
the low flow season, this long shore sediment transport is
dominant which causes sediment to deposite on the southern
side of the ebb tidal delta and elongates the southern sandspit to
narrow the estuary entrance and reorient the main channel.

ACKNOWLEDGMENT

This research was supported by Projects VAST 06.06/19-
20, KC08.16/16-20, and NDT.30.Ru/17 Protocol.

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