BEBs in the lower Volta Delta (Ghana, West Africa)

West African beaches have undergone rapid changes in recent years due to natural and anthropogenic factors (Alves et al., Reference Alves, Angnuureng, Morand and Almar2020). The Volta Delta situated on Ghana’s eastern coast is a prime example of a highly dynamic and erosion-prone region (Figure 1). The Volta Estuary of the Volta Delta is at the mouth of three major West African rivers that drain large parts of Ghana, Togo, Burkina Faso and smaller portions of Côte d’Ivoire, Mali and Benin and accommodate many BEBs that have great significance. These BEBs typically front narrow sandy barriers that are facing significant erosion, posing risks to coastal settlements and natural ecosystems. On the open coast, beaches are wave-dominated, with an average H_s of 1.4 m and peak wave period (T_p) of 11 s (Angnuureng et al., Reference Angnuureng, Jayson-Quashigah, Almar, Stieglitz, Anthony, Aheto and Appeaning Addo2020). The tidal range is about 1 m (Addo et al., Reference Addo, Nicholls, Codjoe and Abu2018). The Volta Delta coast has extensive swamps with intermittent mangrove areas of predominantly red mangrove (Kortatsi et al., Reference Kortatsi, Young and Mensah-Bonsu2005) and savannah woodlands (Boatema et al., Reference Boatema, Addo and Mensah2013). Due to increased flooding and the construction of the Akosombo Dam in 1963 on the Volta River, the BEBs inside the Volta Estuary and adjacent open-coast beaches have experienced rapid shoreline transgression. For example, the open-coast Fuveme community, west of the mouth, lost 37% of its area, resulting in the displacement of people and the destruction of houses with the entire community being lost in November 2021. Ada Foah beach to the east of the mouth suffered from both erosion and flooding, also causing the loss of schools and settlements (Addo et al., Reference Addo, Nicholls, Codjoe and Abu2018). Wave overtopping occurs on the coastal area of the Delta due to its low-lying nature, thus causing salinisation within the BEBs. This has the potential to degrade the freshwater ecosystems within the Delta, perhaps an unexpected consequence arising from BEB erosion. Although there is a lack of studies on the evolution of BEBs in this estuary, it is evident that like the beaches on the open coast, most of the major BEBs near the estuary entrance have also undergone severe erosion over decades since the dam construction. As the shoreline has adjusted to changes in catchment sediment yields, beach erosion has been further exacerbated as residents have attempted ad hoc hard infrastructure protection such as placing rocks on the beach. To effectively manage the BEBs in the Volta Estuary, there is a need for a deeper understanding of their processes, targeted models and management practices with particular attention being paid to the regional and local sediment budgets.

BEBs in south and Southeast China (Asia)

BEBs in China, often encompassing tidal flats, are extensively developed along the S and SE coasts and associated to large rivers like the Yellow, the Yangtze and the Pearl (Figure 1). The most prominent geographical setting of these BEBs is the high supply of fluvial materials (sediment, discharge and nutrients), combined with strong coastal tidal/wave currents and the presence of densely urbanised landscapes (Zhang et al., Reference Zhang, Chen and Luo2016; Wu et al., Reference Wu, Milliman, Zhao, Cao, Zhou and Zhou2018). However, the construction of large dams along with rising marine hazards, for example saltwater intrusion and coastal erosion, has largely affected the habitats on BEBs (Chen et al., Reference Chen, Wang, Finlayson, Chen and Yin2010; Wu et al., Reference Wu, Cheng, Xu, Li and Zheng2016). Consequently, dams now prevent the transport of sufficient sediments into the estuaries, and therefore, BEBs are eroding with hard engineering structures in place to prevent coastal erosion. This is particularly concerning when considering potential seasonal high energy conditions induced by tropical storms (typhoons) from the West Pacific Ocean. Examples of these profoundly modified BEBs can be found in the metropolitan city of Shanghai and Guangzhou inhabited by 18–20 million people. These socio-ecological settings in China’s estuaries are alarming to the stakeholders underscoring the urgent need for legislative action at both municipal and national levels to curb further degradation of BEBs.

BEBs on the Amazon and South Atlantic coasts (Brazil, South America)

Brazil has a broad range of BEBs in its diverse estuarine systems. BEBs along the Marajó estuary, part of the Amazon River estuarine system (Figure 1), are exposed to macro-/mesotides (3–6 m) that modulate the low-to-moderate waves (H_s = 0.5–1.5 m) propagating over the inter- to subtidal sand-/mudbanks (Pereira et al., Reference Pereira, Vila-Concejo, Short, Short and Klein2016). On the eastern side of the estuary, there are 157 beaches along 265 km of mangrove-dominated shoreline, intersected with rivers and creeks forming bays, distributary islands and extensive tidal shoals (Anthony et al., Reference Anthony, Gardel, Gratiot, Proisy, Allison, Dolique and Fromard2010). Some of these BEBs are narrow (up to 50–70 m width) and have a high-gradient intertidal zone (> 5°) with reflective characteristics, composed of medium sand (e.g. Murubira; Figure 2). Other BEBs have intermediate characteristics, are wide (up to 350–450 m) and have a low-gradient intertidal zone (1°) (e.g. Colares; Figure 2).

Figure 2. BEBs case study locations and photographs. For world location, please refer to Figure 1.

In southern Brazil, the microtidal (0.25 m tidal range) Patos Lagoon (Figure 1) plays a significant role in the regional sediment dynamics (Marques et al., Reference Marques, Fernandes, Moraes, Möller and Malcherek2010). Export rates of suspended sediment to the coast are up to 1.37 10⁷ t/year of total suspended matter (Marques et al., Reference Marques, Fernandes, Moraes, Möller and Malcherek2010). The area of fresh-/salt water mixing extends 60 km from the lagoon’s entrance, which is mostly composed of fine sand in the shallower sections transitioning to silt and clay within the deeper channels (Marques et al., Reference Marques, Fernandes, Moraes, Möller and Malcherek2010). BEB morphodynamics inside this estuary are controlled largely by the river discharge, together with the wind patterns. For example, Praia do Laranjal (Figure 2), a BEB bounding the west jetty of the Patos Lagoon mouth, is highly dissipative with a low intertidal gradient (2°) and mostly wave-dominated (H_s = is up to 0.6 m, compared to the average of 1–1.5 m on the open coast) (Tozzi and Calliari, Reference Tozzi and Calliari2000), typically presenting multiple bar systems (Guedes et al., Reference Guedes, Pereira and Calliari2009).

One major issue for BEBs in Brazil, both in the North and in the South and especially with climate change, is the lack of specific tools and models with sufficient local data to help inform management.

BEBs in San Francisco Bay (USA, North America)

San Francisco Bay (Figure 1) has many BEBs, including the urban Crissy Field beach (Figure 2), located 0.5 to 2 km from the entrance on the southern side of the estuary and near the flood tide delta – a sandy BEB connected to a small marsh, facing towards the NE Pacific. Offshore waves that can propagate into the estuary typically approach from the north-west (NW) with H_s between 1 and2 m (peak periods >10s), although it is not unusual for H_s to exceed 5 m outside the mouth during storms (with T_p approaching 20 s). Ocean waves that reach Crissy Field have refracted and decayed with dominant directions from the north-NW and heights between 0.2 and0.4 m. In addition, strong sea breezes over a fetch of 2–3 km can generate high-frequency waves with similar amplitudes, and infragravity waves also occur at this beach. All waves propagate from the west causing strong eastward littoral transport. Given the BEB’s proximity to the bay entrance, the sand supply to Crissy Field is a combination of tidal and wave-driven transport, with sand originating on nearby beaches seawards of the mouth (Barnard et al., Reference Barnard, Foxgrover, Elias, Erikson, Hein, McGann, Mizell, Rosenbauer, Swarzenski, Takesue, Wong and Woodrow2013) (Figure 1). The BEB encloses a marsh and small 0.07 km² tidal lagoon that closes intermittently, typically when the offshore wave height exceeds 3.5 m driving strong littoral drift across the lagoon mouth (Battalio et al., Reference Battalio, Danmeier and Williams2007; Hanes et al., Reference Hanes, Ward and Erikson2011; Hanes and Erikson, Reference Hanes and Erikson2013). Under low-wave conditions, the tidal currents driven by the 1–2.25 m tides can scour the inlet channel and maintain the lagoon–bay connection (Battalio et al., Reference Battalio, Danmeier and Williams2007). When open, outflow from the lagoon builds a small ebb-tide delta and disrupts longshore transport, accounting for a step in the shoreline with the BEB being narrower east of the inlet.

BEBs beyond the influence of ocean waves in San Francisco Bay are shaped by waves generated in the bay (Talke and Stacey, Reference Talke and Stacey2003), with longer period and larger waves incident from directions with longer wind fetch. Wind-generated waves can approach BEBs from multiple directions, resulting in seasonal cycles; for example, Marina Bay beach, further into the estuary, is worked by SW wind waves during winter as well as by refracted NW wind waves during summer (Accordino, Reference Accordino2022). Here, and at other BEBs in the bay, compound events result in morphological change, such as sand overwash fans and beach/marsh erosion. Increasingly BEBs are being included in designs for marsh restoration around the bay (SFEI and Baye, Reference Baye2020).

Swell-dominated BEBs in SE Australia

The coast of SE Australia is microtidal with mean tidal ranges of 1.6 m and 1.3 m for spring and neap tides, respectively. It receives swells with H_s of 1.6 m and a 10-s peak period (Short and Trenaman, Reference Short and Trenaman1992). This moderate wave climate has important repercussions for those BEBs located inside estuaries with wide mouths that allow swell penetration (Vila-Concejo et al., Reference Vila-Concejo, Hughes, Short and Ranasinghe2010; Gallop et al., Reference Gallop, Vila-Concejo, Fellowes, Harley, Rahbani and Largier2020b). Indeed, the wave energy controlling BEB morphodynamics in those estuaries is dominated by swell waves under all conditions, particularly under high-energy conditions (Rahbani et al., Reference Rahbani, Vila-Concejo, Fellowes, Gallop, Winkler-Prins and Largier2022). The relatively recent urban development of Australian cities and the high wave energy in the open coast have led to engineering developments inside estuaries (Figure 2). For example, Sydney Airport and its commercial port were developed in Gamay estuary (Aboriginal name of Botany Bay) and the engineering works including coastal reclamation, river deviation, revetments, seawalls and dredging led to the erosion of urban BEBs that were deemed sacrificial for the sake of urban development (Fellowes et al., Reference Fellowes, Vila-Concejo, Gallop, Schosberg, de Staercke and Largier2021). At the same time, some of Australia’s most expensive real estate in Sydney Harbour is protected by BEBs (Figure 2), and some of the most prominent erosion hotspots correspond to BEBs, for example Jimmy’s Beach in Port Stephens (Vila-Concejo et al., Reference Vila-Concejo, Gallop, Largier, Jackson and Short2020, Reference Vila-Concejo, Hughes, Short and Ranasinghe2010).

Modified BEBs in the bay of Algeciras (southern Spain, South-Western Europe)

The Bay of Algeciras (Figure 1) faces south into the Strait of Gibraltar, is microtidal (mean spring tidal range 0.98 m) and sheltered from ocean-generated waves. Waves approach mostly from the SE and have significant wave heights (H_s) less than 0.1 m, with 1.5 m H_s being exceeded several times per year (Montes, Reference Montes2021). The Rinconcillo–Palmones System (RPS) on the NW side of the bay includes an urban beach (Rinconcillo) and a sandspit (Palmones) (Figure 2). The RPS is adjacent to Bahía de Algeciras Port, one of Europe’s most important ports.

The Algeciras port interrupts the prevailing northward longshore drift and was enlarged significantly in 2000 and 2010, currently extending more than 1.5 km into the sea. This modified the local wave patterns adjacent to seawalls and jetties. BEBs are very sensitive to changes in wave direction (Gallop et al., Reference Gallop, Vila-Concejo, Fellowes, Harley, Rahbani and Largier2020b), and consequently, the RPS is now rotating counterclockwise because of these changes, except for at the spit end, which is controlled largely by currents at the mouth of the Palmones River. Since 2000, the shoreline has prograded at rates over 4 m/yr. at the southern end of the RPS (next to the port), while the northern area has eroded at a rate of around 1 m/yr (Montes, Reference Montes2021). In areas behind the narrowing beach, there is more frequent damage to private property and infrastructure during storms. As occurs at other BEBs (e.g. Costas et al., Reference Costas, Alejo, Vila-Concejo and Nombela2005; Harris et al., Reference Harris, Vila-Concejo, Austin and Benavente2020), beach recovery at RPS, which does not usually reach pre-storm state, requires several months of calm conditions (Montes, Reference Montes2021).

The RPS has a bimodal longshore drift that transports eroded sand alongshore and into deeper areas offshore (Montes, Reference Montes2021). Northward sediment transport occurs during modal conditions transporting material towards the Palmones river mouth and ebb-tidal delta. From there, sediment can be lost to deeper areas in the Bay of Algeciras as depths greater than 50 m occur very close to the coast. Southward sediment transport occurs during storms, when material is transported from the north, where an eroded dune system occurs (Figure 2) and deposited adjacent to the port. The modified sediment transport pathways, because of the port construction and later expansion, have caused the southward sediment transport mode to now become prevalent.

Artificial BEBs in the Netherlands (North-Western Europe)

Dutch estuarine and lake shores are often lined with hard (i.e. asphalt, concrete and stone) flood defences, which require regular reinforcement to withstand current and future marine processes. In recent years, the creation of artificial beaches (e.g. Prins Hendrikzanddijk; Figure 2) in front of hard defences is a paradigm shift from reinforcement of old coastal infrastructure with hard material to nature-based or hybrid solutions (Perk et al., Reference Perk, van Rijn, Koudstaal and Fordeyn2019). Despite ample experience in nourishing large volumes of sand at the wave-dominated Dutch open coast (Brand et al., Reference Brand, Ramaekers and Lodder2022), the understanding of artificial BEBs mainly stems from a “learning by doing” approach, in which continuous monitoring is key to understanding and predicting their development, ultimately enabling safety assessments.

The BEBs in the northern Netherlands are subjected to locally generated wind waves with mean H_s of 0.1 to 0.3 m, reaching up to 1.5 m. Longshore currents include relatively strong tidal currents (~0.6 m/s) which are strongly influenced by wind-driven circulation (~0.25 m/s) in the (semi-) enclosed regions (Ton et al., Reference Ton, Vuik and Aarninkhof2023). As the nourishment sediment is often coarser than the native material (to limit erosion), the surface armouring provided by these coarser sediments causes beach response to be mostly event-driven.

The subsequent equilibration of the profile and planform shape by natural forces depends on the orientation and geometry of the beach with respect to the hydrodynamic forcing. Cross-shore profile adjustment often involves a strong retreat and steepening of the beach face, coinciding with the development of a more concave upward profile and a relatively stable platform at water depths around the depth of closure (Hallermeier, Reference Hallermeier1980, Reference Hallermeier1978), where the surface waves reach the limit of their erosive action (Ton et al., Reference Ton, Vuik and Aarninkhof2021). In addition, longshore drift further redistributes and sorts the nourished sediment, leading to beach rotation, spit formation (10s of meters per year) and the development of cuspate shorelines (van Kouwen et al., Reference van Kouwen, Ton, Vos, Vijverberg, Reniers and Aarninkhof2023).