Morphology of estuaries

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This article provides an overview of the morphological characteristics of estuarine systems occurring around the world. Estuarine morphology is largely determined by self-organizing dynamics. The hydrodynamic features of tides and waves that shape estuarine morphology through local erosion, sedimentation and transport processes are themselves strongly influenced by estuarine morphology. This makes estuaries active morphodynamic systems that evolve autonomously in response to interventions of any kind. Understanding estuarine morphodynamics is therefore a prerequisite for effective estuarine management.

This article first summarizes the main principles of estuarine morphology and underlying dynamics, according to which a classification scheme is introduced. This is followed by a more detailed discussion of particular estuaries, which are exemplary of different types of estuarine systems.



Definition of estuarine systems

The Latin word “aestuarium” means: tidal inlet. Based on morphologic considerations, we adopt here another definition of estuarine systems:

A coastal inlet shaped in the Holocene era by natural erosion, sedimentation and transport processes.

Figure 1: World distribution of coastal plains.

Estuaries defined in this way include deltas and lagoons that communicate with the sea. However, coastal systems with a morphology strongly constrained by pre-existing geology (fjords, rias) or by engineering works are excluded. Geological constraints are rarely absent from coastal systems, but in many cases their influence on morphological development is minor compared to the influence of sediment dynamics. This is the case, in particular, for estuarine systems which have developed by marine transgression of a gently sloping coastal plain. Coastal plains are present along many coasts, as shown in figure 1. The estuarine systems considered here are typically situated in these zones.

From the above definition we can expect that estuarine systems with similar sediment inflow (quantity and quality of sediment), similar river discharge, similar tide and similar wave climate will exhibit similar morphologic characteristics. In practice, situations where these factors are exactly the same hardly exist. Morphologically, the estuary family is therefore highly diverse.


Morphodynamic feedback

Morphology and the forcing agents, waves and currents, mutually interact: while morphology is shaped by currents and waves, it modifies current and wave patterns at the same time. This mutual interaction reduces the diversity of estuarine morphologies occurring in reality. For example, when a channel bed is scoured by strong currents, the channel depth increases, which entails a decrease of the current strength (negative feedback). Interaction occurs at different spatial and temporal scales. For example, sediment import in an estuarine system by tidal currents modifies the overall morphology, which in turn modifies the tidal characteristics and the sediment import in the system [1].

Morphodynamic feedback acts in a way to select certain morphologic patterns. This is explained in the articles Stability models and Rhythmic shoreline features. Field observations show that estuarine systems, where the relative importance of river-induced, wave-induced and tide-induced processes is similar, have many morphologic features in common.


Tide-dominated systems [2]

Figure 2: World distribution of macrotidal coastal zones, where the maximum tidal range exceeds 4 m.

Tide-dominated estuarine systems occur on coasts with strong semi-diurnal tides, see figure 2. These estuaries are characterised by a wide mouth; estuarine channels are narrowing inland. Examples are the Charente and the Hooghly estuaries. A mouth barrier is absent or reworked into a submarine ebb-tidal delta. Channels are scoured into old river sediments or recent marine deposits, a process that has mainly taken place over the past millennia when the marine transgression has stabilized close to current sea level. At the head of the estuary a single main channel connects to the river upstream. Tidal flats are present along the channels; they are mostly built with sediment imported from the sea. An example is Gomso Bay. The highest landward parts of tidal flats develop into vegetated salt marshes, unless this is prevented by frequent strong wave action. These marshes are flooded only at high water. The coarsest sediments are found at the estuarine mouth, where strong tide- and wave-induced currents act on the bed. Fine sediments are deposited on the tidal flats and in the inland channels. Most of the fine sediments in the upper estuarine zone are of fluvial origin. See the article Coastal and marine sediments for a more detailed discussion of sediment characteristics.

Figure 3: Schematic picture of a flood and ebb dominant flow channels in a meandering channel system.

Channels are deeply scoured if the channel bed is sufficiently erodible, but they can remain shallow if the substrate is very hard or if the substrate, on the other hand, consists of very mobile non-cohesive fine sediment. Tidal channels are typically meandering, which is the result of non-linear interaction between morphology and flow dynamics - due in particular to the "overshoot" of the flow at channel bends (so-called inertial delay). The same phenomenon also makes that flood and ebb flows tend to follow different paths through the estuary, eventually leading to a multi-channel system of flood and ebb dominated channels [3], as schematically displayed in figure 3. In places where flood and ebb channels intersect, sand transport converges. This creates thresholds, which form an obstacle to shipping. In order to prevent nuisance to shipping, these thresholds must be dredged regularly. An example is the Western Scheldt. Lateral migration of meandering channels occurs in estuaries with strong tides if the channel bed consists of sufficiently mobile sediments. Fast channel migration is observed, for example, in the mega-tidal Baie du Mont Saint Michel [4]. Migrating channels can reshape the estuarine landscape in a quasi-cyclic process by their strong lateral scouring power.

The tidal wave is distorted when propagating up-estuary. Higher harmonic components are generated with frequencies that are multiples of the frequency of the dominant semi-diurnal tidal frequency M2. The harmonic M4 tide is particularly relevant, because it generates flood currents of different strength compared to ebb currents. For strongly converging (upstream narrowing) estuaries the tidal amplitude increases; after reaching a maximum the tidal amplitude decreases further upstream where the fluvial influence becomes substantial. In most tide-dominated estuaries the high-water (HW) crest of the tidal wave travels faster than the low-water (LW) trough, due to the greater water depth at HW compared to LW. In this case an asymmetry develops with shorter flood duration and longer ebb duration. Therefore, flood currents are generally stronger than ebb currents in the lower part of the estuary; this favours import of marine sediment. Estuarine circulation, driven by salinity gradients, also contributes to sediment import. Both processes contribute to the development of a high turbidity zone in the estuary, the so-called estuarine turbidity maximum. However, under conditions of high river discharge, sediment export dominates over import. Tide-induced import and river-induced export both contribute to the net long-term sediment balance of the estuary [5]. A more detailed discussion of the various estuarine transport processes is given in the articles Tidal asymmetry and tidal basin morphodynamics and Estuarine circulation.


Wave-dominated systems

Wave-dominated systems are characterised by a coastal barrier, built shoreward of the breaking zone by wave-induced cross-shore sediment transport and longshore sediment transport. Breaching of a coastal barrier may occur under conditions of high storm surges or extreme river discharge. If the coastal barrier is backed by a low-lying wide coastal plain, the sea will scour a large inlet in the coastal barrier and transforms the coastal plain into a lagoon. Examples are the Curonian Lagoon and Mussulo Lagoon. If a lagoon is situated on a mesotidal or macrotidal coast, the inlet channel will be scoured (depth and width) such that the peak tidal velocity prevents restoration of the sandy barrier by longshore sand transport; a corresponding peak tidal velocity of around 1 m/s is generally observed in lagoon inlet channels[6][7]. Tidal currents also scour a channel system inside the lagoon; part of the eroded sediments are exported and deposited in an ebb-tidal delta. Another part of the sediment is deposited in the lagoon to form extensive tidal flats. An example is the Wadden Sea. The slope of the coastal plain determines the landward lagoon boundaries. The planform of coastal lagoons is therefore often rectangular and laterally (longshore) elongate in the case of a steep coastal plain slope. An example is Willapa Bay.

In short lagoons the water level oscillates with the offshore tide. Part of the flood water entering the lagoon runs over tidal flats, while ebb flow is mainly confined to the channels. Hence, tidal flats are usually flood dominated and channels ebb dominated. Propagation of high water (HW) into the lagoon is delayed by flood expansion over the tidal flats. Flood duration is therefore longer than ebb duration in cases where tidal motion is not friction dominated (large ratio of channel depth over tidal amplitude). For this reason too, ebb currents in the channels are generally stronger than flood currents. On the other hand, net sedimentation on tidal flats is favoured as a consequence of the time lag involved in sediment deposition and resuspension [8]. The finest sediments settle near the landward boundaries of the tidal flats, where salt marshes develop. Accretion of tidal flats and growth of salt marshes is limited, however, by the scouring action of waves in periods of strong winds [9][10].

If the tidal amplitude is small (microtidal coast), barrier breach can occur due to high river flow[11]. River flow can be temporarily very small; in such a low-discharge period the sea inlet can be closed again by longshore sand transport. Closure is avoided if discharges through the inlet (due to tides, river flow or wind-induced oscillations) remain sufficiently high, i.e., maximum velocity not much less than 1 m/s. Currents inside microtidal lagoons are generally much smaller than 1 m/s; if they are insufficient for sediment transport, the lagoon will not keep pace with sea-level rise and become progressively deeper. This will be the case for many lagoons with small fluvial sediment supply that are situated on microtidal coasts, such as the Curonian Lagoon.


River-dominated systems [12]

A protruding river delta develops if the fluvial sediment discharge is sufficiently high. However, in the case of strong longshore sand transport (littoral drift) fluvial sediment may be redistributed along the shoreline, especially if the fluvial grainsize does not exceed the grainsize of the sediment transported alongshore. In the geological past, some large rivers have eroded a deep canyon on the continental shelf; this also hampers development of a protruding river delta.

The delta protuberance arises by deposition of fluvial sediment around the tip of the river channel. When the outflow channel extends seaward and when the shoal at the tip of the channel grows, the hydraulic head decreases and river flow is impeded. The river will then seek other outflow pathways. When an alternative outflow path is found, a new distributary develops. The direction in which a new delta protrusion grows depends on the shoreline orientation at the new outlet channel and on the prevailing incidence angle of the highest incoming waves. The former outlet channel may remain open if the fluvial discharge is high enough. However, if the fluvial sediment load is very high, the former channel will become clogged and be abandoned; its protrusion will subsequently erode. Examples are the Yellow River delta and the Mississippi delta. Large river deltas are generally characterised by a series of active (growing) and inactive (eroding) delta outcrops. An example is the Mahakam delta.

In the case of substantial littoral drift, abandoned delta protrusions situated near an active protrusion are reworked into spits at one or both sides of the active protrusion (the so-called delta lobes). The Ebro delta is an example. See the article Wave-dominated river deltas for a more detailed discussion.

Littoral drift contributes to obstructing the river mouth. If longshore transport is so strong that it cannot bypass the river mouth (due to high fluvial water discharge), the downdrift river bank will erode and the river mouth will shift in downdrift direction. In some cases the river mouth can be shifted in downdrift direction over large distances; the river flows a long way behind a sand spit parallel to the coast before it debouches into the sea (case of the Senegal River delta).

River damming during the past decades (or century) has strongly reduced the sediment load of many rivers. Most river deltas are therefore in a stage of regression.


Mixed estuarine systems

Many estuaries belong to an intermediate class, where all three forcing agents, tide, waves and river discharge, play a significant role. The influence of waves decreases with upstream distance from the mouth (except in some wide estuaries oriented along the prevailing wind direction). The opposite holds for the river influence due to downstream widening of the estuary. The inner region of mixed estuaries has morphologic characteristics similar to tide-dominated systems. The major difference occurs at the inlet zone, where a mouth bar is present.

In the case of estuaries with a high fluvial sediment supply, a mouth bar is formed by deposition of fluvial sediment [13]. Mouth bars occur in many tropical and subtropical estuaries, such as the Hooghly, Mekong, Zambezi, Amazon, Meghna, Fly and Yangtze. The Seine also had a large mouth bar, responsible for the generation of its famous tidal bore (“mascaret”), which disappeared after dredging of the mouth bar in 1960.

Mouth bars can extend inward over a large part of the estuarine zone (tens of kilometres), due to net tide-induced sediment import. For example, the width of the mouth bar in the Qiantang estuary (China) exceeds 100 km [14]. The estuarine mouth zone in mixed estuarine systems is thus often much shallower than the upstream estuarine and riverine zones. A mouth bar is self-sustained, as it generates tidal asymmetry favouring upstream sediment transport - especially in funnel-shaped estuaries (see Tidal asymmetry and tidal basin morphodynamics).

In the case of tide-wind-dominated estuaries, mouth bars are formed by wave-driven longshore transport (littoral drift). The interruption of littoral drift at the estuarine mouth promotes the formation of large migrating ebb-tidal delta shoals[15]. Strong unidirectional littoral drift leads to the formation of a sand spit at the downdrift side of the mouth and a narrow deep inlet channel at the updrift side. Examples are the Columbia River, Dyfi and Willapa Bay.


Estuary classification

Figure 4: Classification of estuarine systems according to the relative influence of tide, waves and river discharge on morphology. This influence is discussed more in detail below, for the estuarine systems indicated in the figure. The relative position of the estuaries in the diagram is somewhat arbitrary, depending on the weight attributed to the various morphological characteristics discussed above.

In line with the above description, estuaries can be classified according to the criteria “tide-dominated”, “wave-dominated” and “river-dominated”. Because many estuaries fall in between these criteria, a scale indicating the relative importance of these criteria is often used, as shown in the triangle diagram [16] of figure 4. Morphologic characteristics of particular estuaries indicated in this figure are discussed below.

The diagram of figure 4 is a qualitative classification tool, not based on quantifiable parameters. Tidal influence can be quantified in terms of tidal range, but the spring-neap tidal variation and the ratio tidal-range-to-depth are also relevant. Wave influence can be quantified by significant wave height. But the significant wave height is variable and periods of very high waves play a major role. The same holds for the wave incidence angle and wave period. River influence can be quantified in terms of mean river discharge, but the discharge variation is at least as relevant. Often more important are even the fluvial sediment discharge and the sediment characteristics. There is no obvious small set of parameters that can be used to quantify the relative influence of tides, waves and river discharge on estuarine morphology [17]. The positioning of estuaries in the classification diagram is thus primarily a matter of expert judgment. The examples discussed below also show that estuaries which are close in the diagram can be rather different. The classification tool should thus be used with care and only provides a rough indication of estuarine morphological characteristics.


Stability of estuarine morphology

In this paragraph several natural or man-made disturbances are reviewed that induce reduction (silting up) or enlargement (erosion) of estuaries which are initially in a state of morphological equilibrium. The first question, however, is whether estuarine equilibrium states can exist. Strict equilibrium, i.e. stationary bathymetry at every location, is clearly impossible because of fluctuating hydrodynamic conditions (waves, tide, river discharge, storm surges, …). However, current understanding of estuarine morphodynamics strongly suggests that conditions should exist in which the long-term average import and export of sediment are in equilibrium[1][18]. A few centuries ago, large estuarine systems existed worldwide. These estuaries survived the past three millennia with a more or less stable sea level. This argument also suggests that a high degree of stability of the long-term average estuarine surface and volume is possible under natural conditions. If this were not the case, the existence of large estuarine systems several centuries ago would be most unlikely. This is also evidence that the sharp decline in area and volume of estuaries that has occurred over the past two centuries is almost entirely due to human interference.

Possible consequences of natural or man-made changes in estuarine conditions are: Birth of estuaries, Growth of estuaries, Decline of estuaries and Disappearance of estuaries. Present understanding of underlying cause-effect relations is summarized below, in qualitative terms.

  • Birth of estuaries.
    • Barrier breach. New estuaries form when natural coastal barriers are breached during severe storm surges, allowing the tide to intrude into back-barrier lowlands. Peat compaction (and extraction) in the back-barrier area can play an important role in increasing the vulnerability to barrier breach and subsequent flooding[19]. The tidal current flowing in and out of the flooded lowland can widen and deepen the breach and scour channels in the floor of the flooded area. If the strength of the current through the breach is strong enough (large flooded area, large tidal range) to prevent closure by longshore drift, the inlet will develop into a new estuary (or tidal lagoon). In the Middle Ages, several estuaries were created in this way in the Dutch lowlands, for example the Western Scheldt and the Texel Inlet (Marsdiep)[20].
    • Shifting river mouth. The outflow to the sea of rivers that carry large amounts of sediment can be impeded by sedimentation of the outflow zone. This will raise the river water level, especially during periods of high runoff. If the river course is not constrained by a valley, the floodwaters will look for another, more efficient path to the sea. In this way a new estuary can be created, while the original estuary may be abandoned. A well-known example is the great shift of the mouth of the Yellow River (Huang He) in the 19th century from the East China Sea to the Bohai Sea[21].
  • Growth of estuaries.
    • Reduction of fluvial sediment load. Equilibrium implies that the estuarine morphology has adjusted such that sediment input (directly from the river or from deposits in the nearshore zone) and sediment output to the sea are on average equal. Reduction of the fluvial sediment load induces morphological adaptation to restore the sediment balance by reducing the scour and transport capacity of the ebb outflow. This is achieved by increasing the channel cross-sectional area, thereby increasing the estuarine volume. Lateral channel expansion is likely to involve loss of unprotected intertidal areas. An example is the Colorado river, which has lost most of its tidal wetlands[22]. The estuary head migrates upstream, while the estuary mouth retreats and the outer delta erodes. Erosion at the estuarine mouth is particularly strong when sediment supply from lateral bank erosion is hampered by protection works. An example is the strong retreat of the Rosetta promontory of the Nile after the construction of upstream reservoirs[23]. Sediment retention behind river dams is a major cause of reduced fluvial sediment load for many rivers worldwide. When sediment is retained far upstream, the upstream river bed is eroded first and it can take a long time for the full impact to reach the estuary.
    • Increase of fluvial discharge. An increase in river discharge without an increase in sediment discharge changes the sediment balance of the estuary from equilibrium to net export, due to the increased erosion and transport capacity of the ebb stream. Restoring the sediment balance is achieved by reduction of the current strength through increase of the channel cross section. An increase in peak river discharge is expected to occur in many temperate regions as a result of climate change[24].
    • Removal of embankments. After removal of embankments, adjacent low-lying areas will be flooded at high tide. The related increase of the tidal prism enhances the erosion and transport capacity of tidal currents and thus induces an increase of the channel volume.
    • Dredging. Due to the nonlinear nature of estuarine morphodynamics, channel dredging can shift an estuary to another persistent morphological state. For example, removal of the mouth bar changes sediment transport patterns by altering the propagation characteristics of the tidal wave into the estuary. The analysis of sediment transport patterns in the Seine estuary provides no indication for natural recovery of the sandy mouth bar dredged in the 1960[25]. However, dredging often promotes a strong accumulation of fine sediments and associated turbidity maximum in estuaries[26], which counteracts the dredging-induced depth increase.
  • Decline of estuaries.
    • Tidal flat reclamation. The result is opposite to the removal of embankments. The tidal prism decreases as well as the scour capacity of tidal currents, leading to enhanced sedimentation and estuary infilling.
    • Channel fixation. Channel fixation by artificial embankments or other hard structures impedes the natural propensity of tidal channels to migrate and erode channel banks by the mechanisms illustrated in Fig. 3. Channel migration returns the soil fixed by marsh vegetation back to the pool of mobile sediment, thus contributing to sediment export. The opposite, channel fixation, thus promotes net estuary infilling. A well-documented example is the sedimentation that occurred in the Ribble estuary after the construction of channel training walls[27].
    • Increase of fluvial sediment load. The expected result is opposite to the decrease of fluvial sediment load. However, examples of structural increase in fluvial sediment load are exceptional nowadays.
    • Reduced fluvial discharge. In many rivers the discharge has decreased over the past century due to diversion of river water for irrigation or for use by households and industry. Reduction of fluvial discharge generally goes along with a reduction of fluvial sediment load. The two have opposite effects and may cancel each other out, but the effect of reduced sediment load is generally dominant. In cases where the sediment load is not substantially reduced, the estuary will retain sediment and fill in until the sediment balance is restored. This suggests that river discharge and estuary size are correlated. However, this is not necessarily the case; there are many examples of large estuaries (often lagoon or bay type) with small river inflow.
  • Disappearance of estuaries.
    • Marsh progression. Estuaries draining only a limited area of adjacent land develop fresh/brackish marshes near the land borders. These marshes collect fine sand and silt and stimulate the silting of tidal channels by reducing the size of the tidal prism. If they are sufficiently sheltered from wave action, marshes will further develop over time and cover large parts of the estuary[28]. Tidal velocities then become too small to keep the sea entrance open against sand supply by longshore drift. An entrance barrier then will develop that cuts off the estuary from the sea. Two large tidal basins at the coast of North Holland (Bergen Inlet and IJ Inlet) were closed in this way about 3000 years B.P. [29]. The closure process was stimulated by a fast rising tide and associated dominance of flood currents.
    • Entrance barrier. An entrance barrier closing an estuary from the sea can develop by the process described above. An entrance barrier can also develop when an inflowing river is diverted (naturally or by human interference) to another estuary. In the Netherlands, several estuaries where closed by man-made dams in the 1960s and 1970s to protect adjacent low-lying land from flooding.


Estuarine morphology: examples

Figure 5: Location of estuaries, lagoons and river deltas discussed in the text.

Particular estuarine systems, indicated in figure 4, are discussed below. Figure 5 shows the location of these systems on a world map. The selected estuarine systems illustrate morphologies observed in nature for different ratios of the relative influence of tide, waves and river discharge. Differences in estuarine morphology are observed depending on the relative importance of the three criteria tide-dominated, wave-dominated and river-dominated, as described above. The examples further show that tide influence, wave influence and river influence depend on many factors, that all need to be taken into account.

Besides natural forcing agents, engineering interventions (river damming, water diversion, channel dredging, land reclamation) have a profound influence on estuarine morphology. Estuaries which have been completely modified by engineering works are not considered here. However, many of the systems discussed below experience – and will experience in the near future - important morphological change, due to human interventions of the past decades and due to accelerated sea-level rise.

The examples represent a small minority of existing estuarine systems. Therefore, for each example a few other estuarine systems are indicated that can be considered similar from a morphological point of view.

In all the satellite images below the North is toward the top of the figure.


Charente estuary

Figure 6: Charente estuary, French Atlantic coast (Google Earth image).

The Charente [30][31] (figure 6) is a tide-dominated estuary on the Atlantic coast of France, with a mean spring tidal range of 5 m. It is sheltered from ocean waves by several large offshore islands. The channel width at the mouth is about 500 m and the average channel depth about 6-7 m. The maximum spring-tidal velocity in the inlet channel is 0.8 m/s, averaged over the channel cross-section. The average river discharge is 70 m3/s; the corresponding river flow velocity is small compared to the tidal velocities. Peak runoff may exceed 600 m3/s.

The estuary planform exhibits the characteristic funnel shape; the width convergence length is about 10 km. The tide is thus hardly influenced by the weir 50 km upstream. Intertidal areas were partly reclaimed in the past, but the estuary was less severely modified than other similar European estuaries. The tidal wave is substantially distorted when propagating upstream along the estuary. During spring tides, the difference of ebb and flood duration increases along the estuary by more than an hour. As a consequence, maximum flood velocities are higher than maximum ebb velocities at the inner estuary. During neap tides the tidal wave is distorted less, with longer flood duration than ebb duration and smaller flood velocities than ebb velocities.

In periods of medium-low runoff, the Charente estuary is very turbid, with suspended sediment concentrations in excess of 1 g/l and peak values larger than 5 g/l at 1 m above the bed during spring tide. The estuarine turbidity maximum is related to estuarine circulation and tidal asymmetry. Tidal asymmetry favours trapping of suspended sediment during spring tides due to the dominance of flood velocities over ebb velocities and due to a shorter period of low-water slack tide compared to high-water slack tide: sediment brought in suspension by the ebb current is transported upstream by the flood current before settling takes place. During periods of high turbidity the friction experienced by tidal currents is strongly reduced due to the presence of fluid mud patches covering the channel bed.

Similar processes are observed in other tide-dominated estuaries such as the Loire, Weser and Ems.


Columbia River estuary

Figure 7: Columbia River estuary, US Pacific coast (Google Earth image).

The Columbia River estuary [32] [33][34] (figure 7) developed within a drowned river valley, which imposes constraints on the estuary planform. However, the large width of the valley leaves substantial space for the development of morphological features typical for an estuarine environment, such as meandering and braiding river channels, bars, tidal flats and marshes. The intertidal area covers about 20% of the estuarine basin. Without land reclamation that occurred in the past, the intertidal area would be several times larger. The construction of jetties, which started already in the 19th century, has strongly reduced the width of the estuarine mouth, from about 9 km to 3.5 km at present. In the inner basin, the estuarine width displays upstream convergence, as observed usually in estuaries where tidal currents are much stronger than the river-induced current velocity. The mouth region is the deepest part of the estuary with channel depths of about 20 m. The average depth of the inner basin is about 8 m and influenced by dredging works. Estuarine morphodynamics are influenced by tides, waves and river runoff. The average river discharge is 5000-6000 m3/s, with peaks up to 12000 m3/s; higher peaks occurred in the past, before the construction of river dams. The river carries yearly about 10 million tons of sediment into the estuary, mostly fine sand and coarse silt.

The ocean tides are of the mixed type, with a strong diurnal component. The spring-tidal range is about 2.5 m. The relative phases of the M2, O1 and K1 tidal constituents induce tidal asymmetry at the mouth with faster tidal fall than tidal rise [35]. This favours ebb currents over flood currents and export of sediment.

The mouth region is strongly influenced by wave action. The significant height of ocean waves is about 3 m in the winter season, with a period of around 10 s. Although waves are most frequently incident from a west-north-westerly direction, the most energetic waves are from a west-south-westerly direction. Net littoral drift is therefore to the north. High waves from the south-west favour sediment import. Because of tectonic uplift, the relative sea level is more probably lowering rather than rising. Morphodynamic equilibrium then requires that net sediment export through the mouth exceeds the fluvial sediment import into the estuary.

Other estuaries in wide drowned river valleys are the Delaware (US), San Francisco Bay (US) and the Mersey (UK). Their morphological characteristics are similar, although they are less influenced by waves. The Mersey has a much larger tidal range (5 -10 m).


Curonian Lagoon

Figure 8: Curonian Lagoon, Baltic Sea coast. The large green patch is caused by algae blooms (Sentinel image 10 September 2018 https://landsatlook.usgs.gov/sentinel2/viewer.html).

The Curonian lagoon [36] [37] [38] (figure 8), also known as Kurisches Haff, is separated from the Baltic Sea by a narrow sand spit of almost 100 km length. At the northern tip the lagoon is connected to the Baltic Sea by the Klaipeda Strait. The lagoon is on average about 4 m deep. The Klaipeda Strait has been dredged to a depth of around 10 m. There is almost no tidal motion in the Baltic Sea. Fresh water discharge into the lagoon (mainly from the Nemunas river) is on average about 700 m3/s. The salinity in the lagoon is therefore lower than in the Baltic Sea, where the average salinity is about 7 psu. Flushing of Curonian lagoon waters depends mainly on fresh water inflow and large-scale wind-driven circulation inside the lagoon. The residence time of lagoon waters is of the order of half a year.

The sand spit is subject to wind waves generated in the Baltic Sea. The highest waves are coming from the west (about 20% of the time), with heights between 1 and 2 m and period of 7 s and more. These high waves from the west induce a net littoral drift along the spit from west to east. The development of the sand spit started around 8000 BP, when the sea transgressed the Pleistocene floor of the present lagoon. Sand supply by littoral drift kept the spit crest above sea level. Part of the spit is covered with high sand dunes, which prevent overwash by storm waves. The lagoon drowned because the basin behind the spit raised at a slower pace than sea level (by sediment infill and isostatic uplift). Observations indicate that the Curonian spit is broadly in equilibrium with present relative sea-level rise.

Lagoons with similar characteristics are ubiquitous along wave-dominated microtidal coasts, for example the US Gulf coast (Corpus Christie Bay, Galveston Bay, Mobile Bay) and the US Atlantic coast (Pamlico Sound, Great South Bay).


Dyfi estuary

Figure 9: Dyfi estuary, Wales, Irish Sea (Google Earth image).

The Dyfi estuary [39] [40] [41] (figure 9), situated at the west coast of Wales, has developed by marine transgression and infilling of a wide former river valley. The estuary exhibits typical characteristics of a wave-dominated inlet and a tide-dominated inner basin. Fresh water inflow in the basin is small, 30 m3/s on average. The estuary is sandy (medium grain size about 0.25 mm) with a meandering channel system and extensive tidal flats. The average channel depth is 4-5 m and the overall depth 1-2 m.

The mean spring tidal range at the inlet is 4 m; rising tide has a shorter duration than falling tide. Flood currents are stronger than ebb currents in the inner basin. However, the inlet channel is ebb dominated due to a strong ebb jet.

High waves (wave height exceeding 3 m) occur about 5% of the time; the incidence angle is predominantly from western and south-western directions. This results in a northward littoral drift, responsible for the development of the sand spit at the southern inlet boundary. The inlet channel is therefore narrow and kept in a northern position. Net tidally-induced sediment transport in the inlet channel is directed seaward. This sediment loss from the estuary is probably compensated by sediment supply through wave-driven and tide-driven transport in the breaker zone along the southern spit and the northern channel boundary.


Ebro delta

Figure 10: Ebro delta, Spanish Mediterranean coast (Google Earth image).

The Ebro delta on the Spanish Mediterranean coast (figure 10) is a typical example of a wave-dominated river delta [42] [43]. Tidal motion is almost absent. The delta was formed during the past millennia when the runoff sediment load of the Ebro River was high. Due to dam construction on the upper river starting around 1950, the sediment load was reduced more than tenfold, to about 1 million ton/year at present. The average water discharge decreased from 600 m3/s to about 400 m3/s, while peak discharges were more than halved, to about 3 times the average discharge. The reduction of the fluvial discharge had important consequences for the delta morphology. A single outlet channel has remained, with bankfull width and depth of 180 m and 5 m, respectively. The sand fraction was scoured from the top layer of the outlet channel, leaving a coarse (“armoured”) sediment bed.

The river mouth is retreating several tens of meters per year. The delta has become more wave dominated with less fluvial influence. Most frequent and highest waves are coming from easterly directions, with average height of about 1 m and period of 5 s; wave heights of 2-3 m occur exceptionally. The corresponding wave-induced littoral drift produces lateral spread of the delta front to the south and to the north. The delta lobes contain reworked deposits of ancient avulsed outlet channels.

In periods of low to medium river discharge, seawater intrudes the outlet channel as a salt wedge. The length of the salt wedge is determined not only by river discharge, but also by the presence of sills (hard outcrops) in the channel bed. A more detailed discussion is presented in Salt wedge estuaries.

Deltas with similar characteristics include the Danube, Rhône and Po.


Gomso Bay

Figure 11: Gomso Bay, west coast of Korea. (Google Earth image).

Gomso Bay is a macrotidal basin on the west coast of South Korea [44] [45] (figure 11). The tide is semidiurnal; the average tidal range is 4.6m (maximum 8m). River inflow is very small. The basin has a funnel-shaped morphology, characteristic for macrotidal inlets. The water depth of the main channel reaches 20m during spring tide. The maximum ebb current (about 1.5 m/s) is stronger than the maximum flood current. The inner basin is tide-dominated, with large bare tidal flats. The tidal flats have typically an upward convex profile; they are muddy and strongly reworked by bioturbation.

The outer bay is wave dominated with large muddy concave-up tidal flats. Significant offshore wave heights during winter are 2–4 m. The middle part of the basin has sandy channels and shoals.

Macrotidal inlets with similar morphology include Baie de la Somme (France), Morecambe Bay (UK), the estuaries of the Ribble and Dee (UK), Haeju Bay (North Korea) and Baia de Sofala (Mozambique). The Baie du Mont St.Michel (France) with a mean spring tidal range of 10 m has also similar morphologic characteristics; however, the channels in the Baie are very shallow and highly mobile due to the particular type of sediment (“tangue”, non-cohesive fine bioclastic material).


Hooghly estuary

Figure 12: Hooghly estuary, Bay of Bengal, India (Sentinel image).

The Hooghly [46] [47] [48][49] is the most western branch of the Ganges-Brahmaputra delta (figure 12). The average river discharge is estimated at 3500 m3/s, with a yearly peak of 12000 m3/s. The significant wave height at the mouth is rather small - about 0.6 m. The estuary has the characteristic funnel shape. The channel width reduces from 20 km at the mouth to about 6 km at a distance 40 km upstream. The channel depth along the thalweg is about 10-15 m; the width-averaged depth is much lower, about 6-8 m.

The estuary is tide-dominated with a mean spring tidal range of 4 m. The tidal range increases by some 20% over the first 60 km of the estuary. The speed of the tidal high water (HW) propagating into the estuary is about 10 m/s, which is faster than the 7 m/s speed of the tidal low water (LW). At Kolkota, 140 km from the mouth, the period of tidal rise is almost 4 hours shorter than tidal fall. Peak flood currents are therefore substantially stronger than peak ebb currents. At high spring tides a tidal bore develops 50 km downstream from Kolkota. The sediment discharge to the sea is of the order of 20 million ton/year. The estuary is moderately turbid, with surface concentrations of suspended sediment of a few hundred mg/l in the upper estuarine zone and concentrations less than 100 mg/l at the mouth. The upper estuary limit corresponds to the tidal intrusion front, which is located 70-80 km upstream from the mouth.

Estuaries with similar characteristics include the Meghna estuary (Bangladesh), Amazon estuary (Brazil), Fly estuary (New Guinea) and Yangtze estuary (China).




Mahakam delta

Figure 13: Mahakam Delta, East Kalimantan (Borneo) (Landsat image).

The Mahakam [50] [51] [52] [53] is a large tropical river of Kalimantan (Borneo) flowing into the Makassar Strait (figure 13). The river discharge near the delta apex (channel width 500-1000 m, depth 5-10 m) is typically in the range 2000-3000 m3/s. Peak discharges are buffered by large inland lakes. River flow velocities may reach 1.5 m/s. The channel bed along the thalweg consists of consolidated clays. The river has built a large delta, with three main distributaries, which divide over a large number of smaller delta branches. Mouth bars are present at the seaward boundaries of the different distributaries. The depth of the distributaries ranges between 2 and 6 m. Fine sand deposits prevail in the southern delta lobes, while organic mud deposits (interbedded with fine sand) are found in the less active northern branches.

The tidal range in the Makassar Strait is small, between 1 and 2 m. Yet many large funnel-shaped tidal creeks are visible in the satellite image. Tidal currents dominate in the delta branches. Maximum tidal velocities are of the order of 1 m/s. Tidal influence is enhanced by subsidence of the delta.







Mekong delta

Figure 14: Mekong Delta, South Vietnam (Google Earth image).

The Mekong delta [54] [55] [56] [57][58] (figure 14) is among the largest floodplains of the world. The present delta developed during the past 8000 years by the high sediment discharge of the Mekong river, which is estimated at 50-150 Mton/year. Most of the sediment load consists of fine silt. The present sand export to the sea is estimated at 5-9 Mton/year [59]. Initial progradation rates of 20-30 m/year have decreased to 10-20 m/year during the past millennia. The upper part of the delta was formed during the mid-holocene equatorial high-stand (6000 BC) when the sea level was 2.5-4.5 m higher. The delta built out mainly in southern direction, due to an important southward littoral drift. This littoral drift is related to longshore currents (up to 0.55 m/s) and waves (significant wave height of 1.7 m), generated by the strong NE winter monsoon. The largest progradation occurs at the Cap Camau peninsula, some 200 km south of the river mouth. The lower river delta has a well-developed system of beach ridges (low dunes of 3-10 m high) with inter-ridge swamps and mangrove marshes. The subaerial delta is approximately 10 km wide and fronted by a steep subaqueous delta.

The average fresh water discharge of the Mekong is about 15,000 m3/s with peaks of 40,000 m3/s. Two main distributaries (Bassac and Mekong) split in the lower delta into several sub-branches. The largest sub-branch is the Dinh An (northern branch of the Bassac river), which takes almost 30% of the total river runoff. The tidal channels are wider at the mouth than upstream, but the width convergence length is large – about 80 km. The average channel depth is about 7 m at the mouth and 12 m further upstream (Dinh An channel).

The lower delta is under tidal influence. The tide is mainly semidiurnal (M2) with an important diurnal component (K1). The mean tidal range is 2 m and the spring-tidal range 3 m. In periods of low river runoff, peak flood velocities in the Dinh An channel reach 1 m/s and are about 10% higher than peak ebb velocities. Sediment (fine sand and mud) is trapped in the estuary; suspended concentrations reach 0.5 g/l. The sediment grain size is of the order of 0.2 mm. The tidal salinity front moves some 50 km up the estuary during the dry season. During high river flow, suspended sediment concentrations are below 0.1 g/l and seawater is almost completely expulsed from the estuary.

The Indus delta (Pakistan) has characteristics comparable with the Mekong; tide, wave height and solid discharge are similar, but the water discharge is much lower and the suspended load much higher.


Mussulo Lagoon

Figure 15: Mussulo Lagoon, Angola Atlantic coast (Google Earth image).

The rectangular Mussulo Lagoon [60] (figure 15) is situated on the Atlantic coast of Africa, near Luanda. The average tidal range is 1 m (maximum 1.8 m). Sea breeze is the most common wind. Northward sand transport along the coast (in the order of 0.1 Mm3/year, decreasing to the north) is driven by frequent swell waves from the SW with a significant height of 1–1.5 m. The length of the sand barrier separating the lagoon from the ocean has decreased during the past century. A large shoal north of the entrance to the lagoon is a remainder of the previously longer sand spit. The lagoon is sandy without mudflats; tidal flats are sparsely vegetated. The lagoon is situated in an arid region; it receives no fresh water runoff and little organic matter. Distinct ebb and flood channels are bending around tidal flats, which are intersected by shortcut channels.

Other similar lagoons exist along the Persian Gulf coast (Al Jubail, Abu Dabi), and the coast of Tanzania (Lazy Lagoon).

Tidal lagoons of similar dimensions and with similar tidal range and wave climate occur along many microtidal coasts in temperate and subtropical regions. The intertidal zones of these lagoons are covered with densely vegetated marshes, which reduce channel migration dynamics. The production of organic material contributes to raising the intertidal zones in order to keep pace with sea-level rise. Examples are the Venice lagoon and lagoons along the southern US Atlantic coast.



Senegal River delta

Figure 16: Senegal River delta in 2003, Senegal Atlantic coast (Landsat image).

The Senegal River [61] [62] [63] [64] (figure 16), situated on the African Atlantic coast, has a wave dominated delta. A strong littoral drift from north to south shifted the river mouth from its original position (outcrop at the top of the figure) more than 40 km to the south. A narrow sand spit, called “Langue de Barbarie” (less than 1 km wide and less than 5 m high) separates the river from the ocean over a distance of 30 km. The spit has breached several times during the last century. After each breach, the mouth migrated southward with a speed of about 400 m/year, to reach a position close to the 2003 position shown in the figure.

The average discharge of the Senegal River is 600-700 m3/s; during several months each year the discharge is almost nil, whereas peak discharges can exceed 2000 m3/s. Spit breach occurred in the past for extreme river discharges. The average sediment runoff of the Senegal River is about 1 million ton/year; most of the sediment consists of fine silt and clay minerals with grainsize of around 0.005 mm and less. The average channel depth of the lower Senegal river is 6-7 m.

Tides are small; the spring tidal range hardly exceeds 1 m. Ocean waves are coming most of the time from north-western directions. The average wave height is 1.4 m and the wave period about 5 s; wave heights up to 5 m occur exceptionally. A wave- and wind-driven current of 0.3 m/s on average flows along the shore in southward direction; the littoral drift is estimated at 0.5-1 million m3/year. Sand is supplied by the former delta and by shoreward migrating Sahara dunes further northward.

In 2003 the sand spit was breached artificially, to prevent flooding of the town of Saint-Louis (situated at the northern root of the spit) by a high river flood wave. The artificial breach was initially less than 5 m wide and increased to more than 5 km wide in the next 10 years. The southward migration of the new river mouth is not as fast as for previous breaches. Increase of tidal motion, due to tidal wave reflection at the Diama dam built 25 km upstream of Saint-Louis (1986), might be one of the causes.

The Senegal River delta is an extreme example of an alongshore migrating river delta due to littoral drift; another example is the Mono River Delta (Benin). There are many less extreme examples of such deltas, for example the Mahanadi River Delta (India) and the Volta River Delta (Togo).





Wadden Sea

Figure 17: Western Wadden Sea, Netherlands (Google Earth image).

The Wadden Sea [65] [66] (figure 17) is a series of tidal lagoons along the tide- and storm-dominated Dutch-German-Danish North Sea coast. The lagoons developed by marine transgression around 6000 BP of the west- and north-Frisian Pleistocene plain. Breaches of the initial coastal barrier gave rise to numerous tidal lagoons sheltered by barrier islands and mutually separated by submergible tidal divides. The tidal range increases along the coast from about 2 m in the west to 3.5 m in the east. All the lagoons have pronounced ebb-tidal deltas. The largest lagoons occur in the western part of the Wadden Sea. The figure shows the tidal lagoons of the Western Wadden Sea of the Netherlands – from west to east: Texel Inlet, Eijerland Inlet, Vlie Inlet, Ameland Inlet and Frisian Inlet.

The Wadden lagoons are sandy systems, with mostly fine sands (0.1-0.2 mm). The mud fraction (d < 16μ) of the bed top layer (25 cm) is generally low (higher at the end of the summer than at the end of the winter). Even on the highest parts of the tidal flats the mud fraction almost never exceeds 10% and the average fraction is only a few %. Only the most landward part of the tidal flats is vegetated (Salicornia dolichostachya, Spartina anglica). The channel depth is about 15-20 m at the inlets and 4–10 m in the inner basins. The channel system is fairly stable and has a ‘normal’ configuration: Tidal flats are situated at the inner channel bends; channel branches shoot off at the outer channel bends; the strongest curvature occurs where the outer bend meets a boundary.

The maximum spring tidal currents are of the order of 1.5 m/s at the inlet throat and of the order of 1 m/s in the interior channels. Cross-sectionally averaged velocities are about 30% lower. Peak channel currents are slightly stronger during flood than during ebb. Sand from the North Sea enters the Wadden Sea inlets. The net yearly import in the Western Wadden Sea is of the order of 6 Mm3 (average over the period 1935-2005) [67]. This is a little more than needed for keeping pace with sea-level rise (15–20 cm over the past century).

All the Wadden Sea inlets have large ebb-tidal deltas. The ebb-delta shoals migrate along the inlet and the orientation of the main ebb channel varies accordingly. The channel-shoal pattern therefore evolves in a cyclical way, with periodicity depending on the tidal volume of the back-barrier basin[68].

Texel Inlet is the main inlet of the former Zuyderzee, which was dammed off in 1930. Bathymetric surveys indicate that the rate of infilling was very high the first decades after closure, but it has strongly decreased since[67]. Most of the imported sand was taken from the ebb-tidal deltas. The sand volume stored in each ebb-tidal delta was comparable to the volume of the corresponding lagoon. After closure of the Zuyderzee the sand volumes of the Texel and Vlie ebb-tidal deltas have strongly decreased.

A tidal lagoon system similar to the Wadden Sea exists at the southern Algarve coast of Portugal.


Western Scheldt and Scheldt estuary

Figure 18: Western Scheldt and Scheldt estuary, Netherlands, Belgium (Sentinel image).

The Western Scheldt – Scheldt estuary [69] [70] [71] (figure 18) is a meso-tidal basin (4 m tidal range), with small river inflow (average 100 m3/s). Wave influence is substantial only at the inlet zone. The seaward part is a wide sandy lagoon, which developed around 1500 BC in the Rhine-Meuse-Delta coastal plain after breaching of a former coastal barrier. Tidal currents scoured a system of multiple ebb- and flood-dominated channels, separated by shoals. The average depth is about 16 m; depths up to 40 m occur at outer channel bends. The intertidal area, which covered in the past more than 3000 ha was reduced by reclamation to less than 1000 ha; reclaimed land is protected by seadikes. The estuary has now a converging shape: width 4-6 km wide at the mouth, decreasing to about 2 km at 80 km upstream.

The river Scheldt enters the Western Scheldt basin at the Dutch-Belgian border; in the past, the river Scheldt was connected to the sea through the more northerly situated Eastern Scheldt basin. The Scheldt is a tidal river, heavily dredged to allow shipping to the harbour of Antwerp (depth navigation channel of 15 m). The tidal channel has a funnel shape: from 1500 m wide at the Dutch-Belgian border to about 300 m, 30 km upstream. The tidal range is highest (5.5 m) in the fresh-salt transition zone near Antwerp. Tidal motion remains substantial more than 100 km further upstream.

Several estuaries with similar characteristics exist in Western Europe: Elbe, Weser, Ems, Humber, Seine, Loire. All these estuaries were strongly modified during the past century for navigation purposes (channel deepening, tidal flat reclamation, infill of secondary channels). The Delaware, Potomac and James River are estuaries with comparable characteristics in the US.


Willapa Bay

Figure 19: Willapa Bay on the US Pacific coast (Sentinel image).

Willapa Bay [72] [73] [74] (figure 19) is a rectangular shaped tidal lagoon, sheltered from the Pacific Ocean by a 27 km long sandy spit. The entrance channel situated at the north of the basin is shifted further northward by littoral drift and wave- and current-induced erosion of the northern inlet border. The conditions at the inlet are similar to those at Columbia River mouth, situated 50 km to the south. Highest waves (heights exceeding 10 m with periods of 10-20 s) from a south-westerly direction occur during winter, whereas lower waves from the north-west dominate in other seasons. The inlet channel has a sand-gravel bed; the depth exceeds 20 m. The inner basin is dissected by a network of channels with a substrate of fine sand interbedded with mud; the depth is less than 10 m. About half of the lagoon area consists of mudflats and marshes with a silt-clay substrate.

The average fresh water inflow is less than 100 m3/s, which is very small compared to the tidal discharges. The tide is semidiurnal (M2) with strong diurnal components (K1, O1); the relative phases favour a longer duration of tidal rise compared to tidal fall. The mean spring-tidal range is 3.5 m. The maximum velocity of tidal currents is 1 m/s; ebb currents in the channels are stronger than flood currents. The tidal flats are flood dominated. The net flow over the tidal flats is flood directed, whereas the net flow in the channels is ebb directed. The tidally averaged sediment flux is seaward. However, sand import into the lagoon is observed under storm conditions.

The Bassin d’Arcachon on the French Atlantic coast has morphologic characteristics similar to those of Willapa Bay.



Yellow River delta

Figure 20: Yellow River Delta in 1989 on the Bohai Sea, China (Landsat image).

The Yellow River [75] [76] (Huanghe, figure 20) has the highest suspended sediment concentration of all rivers in the world: about 20 g/l on average and 200 g/l during peak flow. The sediment load consists of silt (grainsize of around 0.01 mm and less) originating from the large loess plateau at the upper reaches of the river. In the past, sediment runoff was of the order of 1000 Mton/year and the average water discharge close to 2000 m3/s. The river runoff and sediment load to the sea have strongly decreased during the past decades to about 20% for the river runoff and about 15% for the sediment discharge, by irrigation works and the construction of water reservoirs. The major proportion of the sediment load is discharged offshore.

The course of the lower Yellow River has changed several times, due to siltation and clogging of the river outflow channel. Since the mid-19th century, the Yellow River discharges into the Bohai Sea. The delta has typically a single branch, because siltation prevents the existence of a multi-channel delta.

The tidal range is very small (about 1 m) because the river mouth coincides with an amphidromic point of the tidal system in the Bohai Sea. Alongshore tidal currents are substantial; they can reach 1 m/s. During high river runoff the outflow plume of the Yellow River has a higher density than seawater; the plume plunges along the submarine slope as a turbidity current (hyperpycnal flow). Under moderate river flow, the outflow plume is diverted along the coast by tidal currents. Sediment is deposited within a distance of less than 15 km from the river delta. The delta area expanded yearly on average by 10-20 km2; at present, this expansion has almost stopped.

The Mississippi delta expands in a way similar to the Yellow River delta, by accretion around the tip of the river outflow channel. However, the sediment load of the Mississippi is much lower. Hence, several outflow channels co-exist, responsible for the “bird-foot” shape of the Mississippi delta. Both deltas subside due to the weight of sediment deposits; in both cases this subsidence is accelerated by oil extraction.


Zambezi River delta

Figure 21: Zambezi River Delta on the Indian Ocean, Mozambique (Sentinel image).

The Zambezi [77] [78] [79] (figure 21) is the largest river of East Africa, with an average discharge of about 3000 m3/s. The discharge variability was strongly reduced after the construction of river dams upstream; since 2003 the discharge fluctuates seasonally between 1500 and 4000 m3/s. The sediment discharge is estimated at 40±10 Mm3/year. The delta has a large dune area vegetated with grassland and shrubs. The seaward delta fringe, which is flooded at high river runoff, is covered with mangrove forest; mudflats occur at the seaward side.

The tide is semidiurnal; the mean spring-tidal range is about 4 m. The channels of the two main distributaries have a funnel-shaped mouth, indicative of strong tidal influence. Tidal influence is felt up to 80 km upstream at low river discharge. Tidal currents reach 1.5 m/s near the estuarine mouth during spring tide, which is almost an order of magnitude larger than the river flow velocity. The channels near the entrance are nevertheless very shallow. The deepest channel has a depth of about 5 m and elsewhere depths are between 2 and 4 m. The estuarine delta morphology is highly variable, with meandering and braiding channels and migrating sandbanks.

The morphodynamics of the mouth region is influenced by wave action. The significant wave height is 1.3 m (peak period 7 s) and the dominant wind direction is from the south-east, producing a substantial northward littoral drift. This is illustrated by the channel orientation of the smaller distributaries. South of the large northern Chinde inlet the coastline has prograded about 2 km during the last 40 years.

The Niger delta (Nigeria) and the Godavari delta (India) have morphological characteristics similar to the Zambezi delta. They are also influenced by river discharge, tides and waves, but the tidal influence is less (tidal range of about 2 m).



Related articles

Tidal asymmetry and tidal basin morphodynamics
Estuarine turbidity maximum
Ocean and shelf tides
Salt wedge estuaries
Wave-dominated river deltas
Estuarine circulation
Definitions, processes and models in morphology
Classification of sandy coastlines
Coastal and marine sediments
Seawater intrusion and mixing in estuaries
Physical processes and morphology of synchronous estuaries
Estuarine morphological modelling


Further reading

Colin Woodroffe (2002) Coasts, form, processes and evolution. Cambridge Univ. Press, 623 pp.

David Prandle (2009) Estuaries. Dynamics, Mixing, Sedimentation and Morphology. Cambridge University Press, 248 pp.

Treatise on Estuarine and Coastal Science (2011) Eric Wolanski and Donald McLusky (Editors), Elsevier


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Citation: Job Dronkers (2021): Morphology of estuaries. Available from http://www.coastalwiki.org/wiki/Morphology_of_estuaries [accessed on 31-10-2024]