Comparison of the Causes of Erosion–Deposition between Yellow River, Yangtze River, and Mekong River Subaqueous Delta l: Model Building

Abstract

An estuary delta is an area with active human economic activities and a fragile natural ecological environment. With the intensification of global changes and human activities, coastal and seabed erosion around the world is becoming more and more serious. This study compared the hydrodynamic effect and sediment diffusion path at the Yellow River subaqueous delta (river control type) and the Yangtze River subaqueous delta (tide-river type) in the East Asian monsoon area using a Delft 3D numerical simulation to analyse the causes of the distribution of accumulation and erosion landform in the different types of subaqueous deltas. This study found that the river deltas were dominated by the river when the accumulation landforms concentrated in the direction of the Coriolis forces, which was due to hydrodynamic erosion driven by wind, and the sediment diffusion range was mainly concentrated in shallow water areas (water depth < 6 m), resulting the Yellow River subaqueous delta presenting the pattern of “northern erosion and south accumulation”. The Yangtze River subaqueous delta was controlled by tidal effects, making the southern part of the estuary more susceptible to erosion. The research results can not only further deepen the understanding of the physical process and mechanism of erosion and deposition in the subaqueous delta but also provide stronger scientific support for the deltas’ ecological environment protection, geological environment safety, and disaster geology prevention.

1. Introduction

Since the 1950s, the amounts of sediment transported by large East Asian rivers have decreased significantly due to the impacts of human activities, such as reservoirs and dams [1,2,3,4]. The erosion and deposition process is a main environmental degradation threat [5] because water-induced soil erosion can cause land degradation [6].

The Yellow River delta is a modern estuary delta that was formed by the Yellow River, which transports a large amount of sediment to the Bohai Sea [7] (Figure 1). The coastline of the Yellow River delta is 227 km and the area of the intertidal zone and subaqueous delta is 5129 km² [8]. It is famous for its high sediment transport, second only to the Amazon River [9]. The large amount of sediment carried by its runoff plays an important role in shaping the modern Yellow River delta [10]. Since 1976, the Yellow River delta has been increasingly affected by strong winds [11]. The increased dynamics of the ocean caused by the increase in strong winds means that the Yellow River needs to transport more sediment into the sea to maintain the delta’s growth trend. However, during 1950–2018, the water and sediment transported by the Yellow River significantly decreased. From 1999 to 2008, the average annual runoff was 27.7% of the runoff from 1950 to 1959, while the amount of suspended sediment was only 11.8% from 1950 to 1959 [12]. Further, from 2009 to 2018, the amount was less than 50% of that from 1999 to 2008 [1]. Due to the changes in the amounts of suspended sediment transported by the Yellow River in the past 70 years, the geomorphological evolution of the Yellow River subaqueous delta experienced three different stages: rapid accumulation, moderate accumulation, and slow accumulation [13].

Further, every increase of 1 × 10⁸ t/a in the suspended sediment amount transported by the river causes the subaqueous delta to deposit 3.28 km²/a. On the one-year and three-year scales, the critical sediment amounts transported by the Yellow River with regard to the subaqueous delta accumulation and erosion balance were 1.79 × 10⁸ t/a and 1.29 × 10⁸ t/a, respectively [13]. However, after 2005, the high concentration of suspended sediment transported by the Yellow River was restricted to the subaqueous delta and a 12 m water depth due to the impact of human activities [14], resulting in increases in the sediment accumulation rates in the subaqueous delta, while the sediment amount with regards to the subaqueous delta accumulation and erosion balance has reduced to 0.5 × 10⁸ m³/a [15].

Since the end of the 1990s, the amounts of sediment transported by the Yangtze River have shown an obvious downward trend [4] (Figure 2). During 2013–2015, the amounts decreased to 1.20 × 10⁸ tons, which was less than one-fifth of the amount in 1964. However, if the Yangtze River delta reaches a balance between erosion and accumulation, the amount needs to exceed 6.0 × 10⁸ tons [16]. Further, the shear stress on the bottom bed during storms is greater than the critical shear stress of the sediment [17]. This leads to erosion in the Yangtze River course within the mouth and the sandbar area. The Yangtze River subaqueous delta was also eroded [18]. The accelerated erosion process could induce deltaic ecosystem changes [19].

Other than the Yellow River and Yangtze River, the runoff and sediment fluxes of the Mekong River changed significantly due to natural processes and human activities (Figure 3). The amount of sediment transported by the Mekong River between 2012 and 2015 was only 43.1 × 10⁶ t/a, which was less than 30% of the amount before 1992 [2]. This resulted in almost no accumulation of river sediments in the Mekong subaqueous delta after the construction of the dam [20], and the sea bed under the action of the monsoon was subjected to strong shear stress [21], which caused the coastal coastline growth of the Mekong Delta to gradually decrease from 7.8 m/a to 2.8 m/a from 1973 to 2005 and then become −140 m/a after 2005. The net increase in land area in the Mekong Delta also slowed down, with the average rate dropping from 4.3 km²/a (1973–1979) to 1.0 km²/a (1995–2005), and then to −0.05 km²/a (2005–2015) [22]. Therefore, around 2005, the Mekong Delta changed from a constructive delta to an erosive delta. In addition, not only did the land area of the Mekong Delta gradually decrease but its subaqueous delta was also gradually eroded and accompanied by the formation of scouring grooves [22].

In the estuary delta area adjacent to the bay, the later transformation of the sediments [23,24,25,26] and the delta sedimentary characteristics, such as beach erosion, topography, and coastline evolution [27,28,29,30], are all affected by ocean dynamics. The erosion and accumulation of a subaqueous delta are caused by the combined effect of suspended sediment deposition and hydrodynamic scouring [31]. The wind is the most important driving force of waves and currents and it is an important factor that affects the direction and distance of suspended sediment diffusion [32]. Therefore, wind, as one of the driving forces of sediment diffusion and transport, is necessary to consider when analyzing the influence of different seasons and different wind directions on the diffusion of sediment under the influence of monsoon climate [33].

To summarise, even within the same East Asian monsoon region and with the same source (three-river source), the erosion and accumulation control factors were different in the different control types of the Yellow River (river control type), Yangtze River (tide-river shape), and Mekong River (tide-wave shape) subaqueous deltas. However, as typical East Asian deltas, the amount of the runoff and sediment transported by rivers was significantly reduced due to human activities, which led to different degrees of erosion in these deltas [25]. Although the previous studies defined the distribution characteristics of erosion and accumulation landforms in the three subaqueous deltas, the formation mechanism of the distribution characteristics remains unheeded. The types of river deltas may be changed with the reduction in the amount of sediment transported by the rivers.

Therefore, this study intended to build a model to analyze the combined effect of sediment diffusion and hydrodynamics in East Asian estuaries through simulation technology to identify the formation mechanism and control factors of erosion and accumulation landforms at the three different types of major estuary deltas in East Asia. The research results can not only further deepen the understanding of the physical process and mechanism of erosion and deposition in subaqueous deltas, but also provide stronger scientific support for these deltas’ ecological environment protection, geological environment safety, and disaster geology prevention. They can also lay a foundation for the rapid assessment of erosion and accumulation conditions in subaqueous deltas.

2. Method

The Delft 3D software and model were used to simulate the sediment diffusion and shear stress on the bottom beds of the Yellow River, Yangtze River, and Mekong River subaqueous deltas during the flood and dry seasons. The simulated results in the Yellow River subaqueous delta were used to verify the accuracy of the model. The simulated results in the Yangtze River subaqueous delta were used to verify whether the model can be applied to other subaqueous deltas. Then, the verified model was used to simulate the sediment diffusion and the shear stress on the bottom bed in the Mekong River.

2.1. Mathematical Model

The Delft 3D software was developed by the Dutch Delft Hydraulic Research Institute. It is a modular three-dimensional hydrodynamic water quality simulation system, including water flow, hydrodynamics, waves, water quality, and ecology, which can accurately calculate 2D or 3D currents, waves, water quality, sediment transport, ecology, bottom landforms, and interactions between processes. Delft3D-Flow is the main module for simulating hydrodynamic conditions. This module is based on the Navier–Stokes equation and conforms to the Boussinesq assumption. It can accurately simulate estuary deltas and bays with shallow water depths. The ADI calculation method is used to discretely solve the governing equations in the set coordinates. When the influence of vertical acceleration is ignored, the equation of water continuity under static water pressure [34] is

∂ξ/∂t + 1/(G_ξξG_ηη)^0.5 × ∂[(D + ξ)U G_ηη^0.5]/∂ξ + 1/(G_ξξG_ηη)^0.5 × ∂[(D + ξ)U G_ξξ^0.5]/∂η = Q

(1)

In Formula (1), Q represents the effect of the source and sink, such as drainage, precipitation, and evaporation.

In three-dimensional fluids, the momentum equations of ξ and η (the orthogonal coordinate directions) are

∂u/∂t + u/G_ξξ^0.5 × ∂u/∂ξ + v/G_ηη^0.5 × ∂u/∂η + uv/(G_ξξG_ηη)^0.5 × ∂ G_ξξ^0.5/∂η − v²/(G_ξξG_ηη)^0.5 × ∂ G_ηη^0.5/∂ξ+ ω/(D + ξ) × ∂u/∂σ = fv − P_ξ/ρ₀ G_ξξ^0.5 + F_ξ + 1/(D + ξ)² × ∂(v_v∂u/∂σ)/∂σ + M_ξ

(2)

∂v/∂t + u/G_ξξ^0.5 × ∂v/∂ξ + v/G_ηη^0.5 × ∂v/∂η + uv/(G_ξξG_ηη)^0.5 × ∂G_ξξ^0.5/∂_ξ − u²/(G_ξξG_ηη)^0.5 × ∂G_ηη^0.5/∂η + ω/(D + ξ) × ∂v/∂σ = − fu − P_η/ρ₀G_ηη^0.5 + F_η + 1/(D + ξ)² × ∂(v_v∂u/∂σ)/∂σ + M_η

(3)

Here, P_ξ and P_η are pressure gradients, F_ξ and F_η represent Reynolds stresses, G = x₂ + y₂ represents the coordinate conversion coefficients between Cartesian coordinates (x, y) and orthogonal curve coordinates (ξ, η), D is the relative water depth, and Mξ and Mη are the momentum of the source and sink, respectively.

The wave module uses the SWAN model. The SWAN model is the most common solution model for wave conservation equations and was successfully applied in various environments, including shallow water estuaries [35]. The model uses a fully implicit finite difference scheme, which is unconditionally stable so that the calculation of the spatial grid and time step will not be limited. The wave conservation equation of the source terms of the equilibrium equation, which include wind-induced waves, deep fragmentation, wave interaction, four-wave interaction, fragmentation, and friction terms, is

∂N/∂t + ∂(c_gxN)/∂x + ∂(c_gyN)/∂y + ∂(c_σN)/∂σ + ∂(c_θN)/∂θ = S/σ

(4)

where t is time; x and y are the horizontal coordinates; θ is the direction of wave propagation; c = σ/k is the phase velocity of the wave; c_gx and c_gy are the x and y components of the wave group velocity c_g; N is the ratio of the wave energy to the wave frequency σ; and S represents the change in wave energy, reflecting the nonlinear wave interactions, frictional dissipation, wave growth, and wave attenuation. When considering the influence of the current field, the wave action N(σ, θ) (the ratio of the energy density E(σ, θ) to the relative frequency σ) is conserved [36]. The amount of action changes with time and space.

In Formula (4), the first term on the left is the rate of change of N(σ, θ) with time; the second and third terms represent the propagation of N(σ, θ) in the x and y directions, respectively; the fourth term represents the changes in N(σ, θ) in space due to the current field and water depth; and the fifth term represents changes due to N(σ, θ) propagation in space, i.e., the water depth and refraction of the current field.

2.2. Model Building

The three simulation areas were divided into 1.0 km × 1.0 km grids, and the time step was 1 min. The boundary conditions of the area connected with the open sea were provided by the harmonic constants of the four main tidal components.

2.2.1. The Yellow River Subaqueous Delta Simulation

In order to analyze the impact of the decrease in the amount of sediment from the Yellow River on the erosion and deposition of the Yellow River’s subaqueous delta, the simulation times of the “Summer–Autumn Flood” in July and August of 2017 and the “Winter Flood” in November and December in 2017 were selected and compared with the diffusion of water and sediment during the “Summer Flood” period in July and August 2016. The amount of sediment transport and the wind speed and direction were the average values of the “Summer Flood” in July and August 2016, the “Summer Flood” in July and August 2017, and the “Winter Flood” in November and December 2017 (

Table 1. Average values of water, sediment fluxes, and wind velocity in the Yellow River during the summer flood periods in 2016 and 2017 and the winter flood period in 2017.

	Summer Flood (2016)	Summer Flood (2017)	Winter Flood (2017)
Average water flux	680 m3/s	380 m3/s	430 m3/s
Average suspended sediment concentration	2.4 g/L	0.5 g/L	1.5 g/L
Wind velocity	3 m/s	3 m/s	5 m/s
Wind direction	130°	130°	310°

) [37].

2.2.2. The Yangtze River Subaqueous Delta Simulation

The average values of the runoff and sediment fluxes in the flood season in July and August 2018 and the dry season in January and February (

Table 2. Average values of water, sediment fluxes, and wind velocity in the Yangtze River during the flood and dry seasons in 2018.

	Flood Season (July, August)	Dry Season (January, February)
Average water flux	39,000 m3/s	17,000 m3/s
Average suspended sediment concentration	0.2 g/L	0.05 g/L
Wind velocity	4.9 m/s	4.4 m/s
Wind direction	180°	0°

, data from the Yangtze River Sediment Bulletin; Dai and Zhu, 2015) were used as variables for the Yangtze River numerical simulation of the water–sediment diffusion process and the shear stress on the bottom bed in the flood and dry seasons. The results can be used to analyze the influence of sediment transported by the Yangtze River and the wind speed and direction on seabed erosion and deposition.

3. Simulation Results

3.1. Tidal Model Verification

The tidal model was validated using data from August to September 2014 from two locations along the Bohai Sea coast. The correlation between the measured and simulated tidal ranges is shown in Figure 4 and Figure 5. It can be seen that the calculated results were basically consistent with the tidal ranges of the observation.

3.2. Current Velocity Verification

From August 1 to 25 August 2014, the research team conducted continuous observations at the Yellow River estuary for 25 days [38]. The observation data were used to verify the calculation results of the current velocity (Figure 6). Figure 3a shows the change in the measured current velocity and the simulated current velocity with time. From the figure, it can be seen that the trend of the simulated current velocity was basically consistent with the measured current velocity. Figure 6b shows the correlation between the measured current velocity and the simulated current velocity (Pearson’s r = 0.69). As shown in the figure, there was a significant positive correlation between the two. However, there was a difference between the simulated current velocity and the actual current velocity under the action of the wind-induced current because the simulated wind direction and wind velocity were not the same as the actual wind direction and wind velocity.

According to the verification results of the tide and current, the SWAN model used in this study was able to reflect the tide and current changes at the Yellow River estuary, but there were still differences in the specific values. The verification results showed that a qualitative comparative study of suspended sediment transport under the action of wind and waves in the estuary area was feasible. However, if quantitative research is needed, the model needs to be further supplemented and verified.

3.3. Diffusion Range of the Water and Sediment

3.3.1. The Diffusion Simulation Results of the water and Sediment in the Yellow River Subaqueous Delta

The simulation results showed that during the “Summer Flood” in 2016, the flux of sediment transported by the Yellow River was relatively large. Under the influence of the southeast monsoon, the sediment mainly spread to Bohai Bay and affected Laizhou Bay and the central basin of the Bohai Sea (Figure 7a,d). During the “Summer Flood” in 2017, the flux of sediment was reduced; it was no longer able to affect Laizhou Bay, and its impact on Bohai Bay was also limited to the coast of Bohai Bay (Figure 7b,e). In 2017, the flux of sediment in the “Winter Flood” was greater than that of the same year in the “Summer Flood”. Under the influence of the northwest monsoon, the sediment mainly spread towards Laizhou Bay, and it spread along the whole coast of Laizhou Bay (Figure 7c,f).

The simulation results showed that most of the sediment from the Yellow River was deposited in the estuary area, and part of the sediment spread to adjacent sea areas under the combined action of wind, waves, and currents. As shown in Figure 8 and Figure 9, in the absence of wind influence, the incoming water and sediment mainly gathered near the estuary, and a small part was transported to the southeast of Laizhou Bay (Figure 8a and Figure 9a). Based on this, it was speculated that during the period of the northerly wind, the effect of the wind was beneficial to the diffusion of sediment. The simulation results showed that the sediment spread along the west coast of Laizhou Bay under the action of the northeasterly wind in summer and reached the middle part of Laizhou Bay (Figure 8b and Figure 9b); under the action of the northwesterly wind in summer, the diffusion of sediment was similar to that under the action of the northeasterly wind, but the diffusion intensity was greater and the transport distance was longer (Figure 8c and Figure 9c). Since the wind speed in the Yellow River subaqueous delta is greater in winter than in summer, and the Yellow River delta is affected by the monsoon climate, the southeasterly wind prevails in summer, and the normal wind direction in winter is northerly [37]. The wind direction is the same as the Yellow River’s water and sediment diffusion direction, and it is more conducive to the diffusion of water and sediment. Moreover, considering the Yellow River’s “four floods” a year, the results showed that the water and sediment transported by the Yellow River in the “Winter Flood” was not less than that transported in the “Summer Flood” (Table 1); therefore, under the influence of the northwesterly wind in winter, the sediment spreading effect was stronger in the direction of Laizhou Bay, and the sediment was able to cover the entire Laizhou Bay area (Figure 8f and Figure 9f).

In contrast, the southerly wind may inhibit the diffusion of sediment. Under the influence of the southwesterly wind, the sediment in summer gathered at the mouth of the Yellow River and tended to spread to northwestern Bohai Bay, and a small part of it spread to the southeast of the Laizhou Bay mouth (Figure 8d and Figure 9d). Under the action of the southeasterly wind in summer, the sediment mainly spread to Bohai Bay near the northwest of the estuary (Figure 8e and Figure 9e). The simulation results showed that the influence of the southerly wind hindered the transportation of sediment to Laizhou Bay, and thus, the diffusion of sediment to Laizhou Bay was weakened, even to Bohai Bay.

3.3.2. The Diffusion Simulation Results for the Water and Sediment in the Yangtze River Subaqueous Delta

The simulation results showed that in the flood season in 2018 when the runoff and sediment fluxes were larger, the water and sediment diffused to Hangzhou Bay in the south of the Yangtze River estuary (Figure 10a,c); in the dry season, the runoff and sediment fluxes decreased, and the water and sediment fluxes were mainly concentrated near the estuary of the Yangtze River (Figure 10b,d).

The simulation results for the effect of wind on the diffusion of water and sediment showed that under the condition of no wind in summer, the transport intensity to the outside of the Yangtze River estuary was relatively high. Affected by the Coriolis force, the sediment was transported south (Hangzhou Bay and the coast of Fujian and Zhejiang, Figure 11a and Figure 12a). Under the action of the easterly wind in summer, the transportation of water and sediment to the south was weaker than that under no wind, and their transportation to the north of the Yangtze River estuary was strengthened (Figure 11b and Figure 12b). Under the southerly wind in summer, the southward transport of the water and sediment was weaker than that under no wind and the easterly wind, and the transport in the southward direction was strengthened (Figure 11c and Figure 12c). Under the action of the westerly wind in summer, the northward transport intensity of the water and sediment was close to that under the northerly wind, and the offshore direction was weaker than that under no wind and the easterly wind, but stronger than that under the northerly wind (Figure 8d and Figure 9d). The prevailing wind in the Yangtze River estuary in summer is the southerly wind [39]; therefore, the effect of the wind hindered the propagation of the sediment to the south (Hangzhou Bay and the coast of Fujian and Zhejiang). Therefore, the results showed that the sediment transported by the Yangtze River in summer mainly gathered near the Yangtze River mouth, and the offshore and northward transport intensity of the water and sediment was significantly enhanced (Figure 11e and Figure 12e).

The northerly wind prevails in the Yangtze River estuary in winter [39]. Under the influence of the winter northerly wind, the results showed that the transport intensities to the south Hangzhou Bay and the coast of Fujian and Zhejiang were increased, and those to the northward and offshore directions were weakened (Figure 11f and Figure 12f). Although the transport mode of the northerly wind in winter was similar to that in summer, the amount of runoff and sediment transported by the Yangtze River in winter was much smaller than that in summer, the runoff was less than half of that in summer, and the amount of sediment was only one-tenth of that in summer. Therefore, the diffusion range of sediment in winter was still smaller than that in summer (Figure 11e,f and Figure 12e,f).

3.4. Simulation Results of Shear Stress on the Bottom Bed

The wind is the most important driving force of waves and currents; it not only has an important effect on suspended sediment diffusion but also affects shear stress on the bottom bed. Therefore, accounting for wind as one of the driving forces of bottom bed erosion is necessary to analyze the influence of different seasons and different wind directions on the shear stress under the influence of the monsoon climate.

3.4.1. Simulation Results of the Shear Stress on the Bottom Bed of the Yellow River Subaqueous Delta

Combined with modern observation data assuming that the wind speed remained unchanged, under the six conditions of no wind in summer, northeasterly wind in summer, northwesterly wind in summer, southwesterly wind in summer, southeasterly wind in summer, and northeasterly wind in winter, the effect of shear stress changes on the bottom bed affected by changes in the wind direction was simulated. The simulation results showed that under the condition of constant wind speed, the change in wind direction had little effect on the shear stress on the bottom bed (Figure 13a–e). The wind speed in the Yellow River delta in winter was greater than that in summer. As the wind speed increased, the shear stress on the bottom bed along the coast increased accordingly (Figure 13f), indicating that the wind speed was the main factor that affected the shear stress on the bottom bed.

3.4.2. Simulation Results of Shear Stress on the Bottom Bed of the Yangtze River Subaqueous Delta

The changes in the shear stress on the bottom bed were simulated under the conditions of no wind in summer, easterly wind in summer, northerly wind in summer, westerly wind in summer, southerly wind in summer, and northerly wind in winter. The simulation results showed that the shear stress on the bottom bed was similar under the six wind conditions, and the shear stress was stronger around the river month and in the northeastern part of the Yangtze River subaqueous delta (Figure 14). These results illustrated that wind had a small impact on the shear stress.

4. Discussion

4.1. The Characteristics of Erosion and Deposition in the Yellow River Subaqueous Delta

Past studies have found that the pits are distributed in groups in the shallow waters near the northwestern part of the Yellow River delta. The diameters of the entire group of erosion pits reach about 800 m. At the same time, several small pit groups developed in the coastal area of Feiyantan in the northeastern part of the Yellow River delta. Further, under the action of tidal currents and coastal currents, scour troughs formed in the coastal area between Shenxiangou and Dongying Seaport in the northern part of the Yellow River Delta, and eroded landforms formed, such as erosion residues and sand spots. These scoured sediments and sediments carried by tidal currents accumulated outside the river mouth. Additionally, under the interaction of strong wind, wave, and tidal current action, these sediments, which consisted of coarse-grained silty sand, developed large seabed sand waves, sand ridges, and estuary dunes at the water depth of 0.7 m in the front edge of modern estuary deltas, and sand dams at the depth of 7–12 m [40]. In the Yellow River subaqueous delta region, the accumulation pattern appeared as “southern accumulation and northerly erosion”.

In the early winter, the downstream water surface is frozen while the upstream water surface is not frozen, resulting in water storage in the upper reaches of the Yellow River. When the downstream ice surface is broken, the upstream storage water flows out from the “Winter Flood”. The “Winter Flood” induces a large amount of water and sediment transport into the sea in winter. Therefore, under the action of the Coriolis force, the relatively strong winter monsoon effect makes the southward transport volume of sediment greater than the northward transport volume. As a result, the southern part of the Yellow River subaqueous delta (the eastern and southeastern part of Laizhou Bay) had fine-grained sediments transported by the Yellow River [41], while the northern part developed erosive landforms [42], presenting a “south deposition and north erosion” model. The critical erosion stress of the Yellow River delta is about 0.30 Pa [43].

4.2. The Characteristics of Erosion and Deposition in the Yangtze River Subaqueous Delta

The scour troughs in the Yangtze River delta are mainly distributed between Hangzhou Bay and the Zhoushan Islands in the southern part of the delta. The evolution trend shows a trend of accumulation in the north and erosion in the south. The sand ridges are dominated by tidal currents and are mainly distributed at the southern part of Subei Shoal in the northern part of the Yangtze River subaqueous delta and the southeastern outer edge of the delta [42]. The bottom bed changes in the Yangtze River mouth are mainly characterised by “channel erosion and shoal accumulation”, “near-shore (depth < 6.4 m) accumulation and far-shore (6.4 m < depth < 19 m) erosion” outside the mouth, and the accumulation pattern appears as “southern erosion and northerly accumulation” [44].

From the above results, it can be seen that the transportation of water and sediment from the Yangtze River estuary to Hangzhou Bay and the coast of Fujian and Zhejiang were mainly found to be concentrated under no wind, the westerly wind, the easterly wind, and the northerly wind in summer and under the northerly wind in winter. The southerly wind prevailed in the Yangtze River estuary in summer, and the diffusion effect was the strongest under the action of the southerly wind; therefore, the offshore and northward transportation of water and sediment mainly occurred in summer, except for the period of the northerly wind. Therefore, the southward transportation mainly occurred in winter, and the diffusion of water and sediment in the Yangtze River estuary in summer fully confirmed the sediment transportation mode of “summer storage and winter transportation” [45].

5. Conclusions

In the Yellow River delta, the river subaqueous deltas were dominated by rivers when the accumulation landforms concentrated in the direction of the Coriolis force due to hydrodynamic erosion driven by wind, and the sediment diffusion range was mainly concentrated in shallow water areas (water depth < 6 m). In contrast, the subaqueous deltas were dominated by hydrodynamics. For example, the Yellow River delta is located in the East Asian temperate monsoon climate zone. Due to the existence of “winter floods”, there were strong fluxes of water and sediment in both winter and summer in the Yellow River delta. Therefore, under the action of the Coriolis force, the relatively strong winter monsoon effect made the volume of sediment transported southward greater than that transported northward, leading to the development of accumulation in the southern part of the Yellow River subaqueous delta and the development of eroded landforms in the north, presenting a pattern of “northern erosion and south accumulation”.

The sediment transported from the Yangtze River was concentrated in summer. The amount of sediment in summer was more than 10 times that in winter. It spread northward under the action of the southerly wind in summer. In contrast, the wind and waves increased under the action of the northerly wind in winter. Further, the decrease in the amount of sediment, coupled with the influence of the Coriolis force, made the southern part of the estuary more susceptible to erosion.