Hard engineering methods Groynes , Norfolk, UK Groynes are ert or walls perpendicular to the coastline to trap the
sedimentation of
longshore drift to gradually create a beach and for it ongoing protection by eliminating coastal erosion, often made of greenharts, concrete, rock or wood. Material builds up on the downdrift side, where
littoral drift is predominantly in one direction, creating a wider and a more plentiful beach, thereby protecting the coast because the sand material filters and absorbs wave energy. However, there is a corresponding loss of beach material on the updrift side, requiring another groyne there. Groynes do not protect the beach against storm-driven waves and if placed too close together create currents that carry material offshore. Shapes of groynes can be straight, outwardly curved away in opposite direction from downdrift. Groynes are cost-effective, require little maintenance and are one of the most common defences. However, groynes are increasingly viewed as detrimental to the aesthetics of the coastline and face opposition in many coastal communities. Groynes can be considered a "soft" solution because of the beach enhancement. Groyne construction creates a problem known as terminal groyne syndrome. The terminal groyne prevents
longshore drift from bringing material to other nearby places. This is a problem along the Hampshire and Sussex coastline in the UK; e.g., at
Worthing.
Seawalls Walls of concrete and masonry are used to protect a settlement against erosion or flooding. They are typically about high. Older-style vertical seawalls reflected all the energy of the waves back out to sea, and for this purpose were often given recurved crest walls which increased local turbulence, and thus increased entrainment of sand and sediment. During storms, sea walls help longshore drift. Modern seawalls aim to re-direct most of the incident energy in the form of sloping revetments, resulting in low reflected waves and much reduced turbulence. Designs use porous designs of rock, concrete armour (
Tetrapods,
Seabees, SHEDs,
Xblocs, etc.) with flights of steps for beach access. The location of a seawall, must consider the swept prism of the beach profile, the consequences of long-term beach recession and amenity crest level, including cost implications. Sea walls can cause beaches to dissipate. Their presence also alters the landscape that they are trying to protect. Modern examples can be found at Cronulla (NSW, 1985–6), Blackpool (1986–2001), Lincolnshire (1992–1997) and Wallasey (1983–1993). At
Sandwich, Kent the Seabee seawall is buried at the back of the beach under the shingle with crest level at road kerb level. Sea walls typically cost £10,000 per metre (depending on material, height and width), £10,000,000 per km (depending on material, height and width).
Revetments Revetments are slanted or upright blockades, built parallel to the coast, usually towards the back of the beach to protect the area beyond. The most basic revetments consist of timber slants with a possible rock infill. Waves break against the revetments, which dissipate and absorb the energy. The shoreline is protected by the beach material held behind the barriers, as the revetments trap some of the material. They may be watertight, covering the slope completely, or porous, to allow water to filter through after the wave energy has been dissipated. Most revetments do not significantly interfere with transport of longshore drift. Since the wall absorbs energy instead of reflecting, the surf progressively erodes and destroys the revetment; therefore, maintenance is ongoing, as determined by the structural material and product quality. to prevent further erosion of
coastline that is vulnerable to subsidence.
Rock armour Rock armour is large rocks placed at the sea edge using local material. This is generally used to absorb wave energy and hold beach material. Although effective, this solution is unpopular for aesthetic reasons. Longshore drift is not hindered. Rock armour has a limited lifespan, is not effective in storm conditions and reduces recreational values.
Geotextile tubes Geotextile tubes or geotubes are large geotextile bags placed at the sea edge filled with locally available sand slurry. This is generally used to absorb wave energy and hold beach material as riprap does. Often referred to as titan tubes as manufactured by Flint Technical Geosolutions. Longshore drift is not hindered.
Gabions Boulders and rocks are wired into mesh cages and placed in front of areas vulnerable to erosion: sometimes at cliffs edges or at right angles to the beach. When the ocean lands on the gabion, the water drains through leaving sediment, while the structure absorbs a moderate amount of wave energy. Gabions need to be securely tied to protect the structure. Downsides include wear rates and visual intrusiveness.
Offshore breakwater Concrete blocks and/or boulders are sunk offshore to alter wave direction and to filter wave and tide energy. The waves break further offshore and therefore lose erosive power. This leads to wider beaches, which further absorb wave energy.
Dolos has replaced the use of concrete blocks because it is more resistant to wave action and requires less concrete to produce a superior result. Similar concrete objects like Dolos are
A-jack,
Akmon,
Xbloc,
Tetrapod and
Accropode.
Cliff stabilization Cliff stabilization can be accomplished through drainage of excess rainwater of through terracing, planting and wiring to hold cliffs in place.
Entrance training walls Training walls are built to constrain a river or creek as it discharges across a sandy coastline. The walls stabilise and deepen the channel which benefits navigation, flood management, river erosion and water quality, but can cause coastal erosion by interrupting longshore drift. One solution is a sand bypassing system to pump sand under/around the training walls.
Floodgates Storm surge barriers, or
floodgates, were introduced after the
North Sea Flood of 1953 and prevent damage from storm surges or any other type of natural disaster that could harm the area they protect. They are habitually open and allow free passage, but close under threat of a storm surge. The
Thames Barrier is an example of such a structure.
Soft engineering methods , thereby providing habitat for species by facilitative interactions with other habitats such as
tidal flat benthic communities,
seagrasses and
marshes.
Beach replenishment Beach replenishment/nourishment involves importing sand from elsewhere and adding it to the existing beach. The imported sand should be of a similar quality to the existing beach material so it can meld with the natural local processes and without adverse effects. Beach nourishment can be used in combination with groynes. The scheme requires repeated applications on an annual or multi-year cycle.
Sand Dune Stabilization Sand dunes are a common feature of beaches and provide a habitat for many organisms. They are useful when preventing the erosion of beaches, and can catch windblown sand which over time increases the natural formation of the beach. To stabilize sand dunes, foredune flora and backdune flora are planted. Foredune flora are typically plants with a tolerance for salt spray, strong winds and are capable surviving being buried underneath blown sand. Some examples are
Ammophila arenaria,
Honckenya peploides,
Cakile maritima, and
Spartina coarctata. Whereas backdune flora grow into dense patches called dune mats, which helps to hold dune structure. Examples of backdune flora are
Hudsonia tomentosa,
spartina patens, and
Iva imbricata. Plant life has been established as an important stabilizing factor of sand dunes and the loss of it will cause more erosion. To prevent this, noticeboards, leaflets, and beach wardens explain to visitors how to avoid damaging the area. Also, beach areas can be closed to the public to reduce damage. Another option is fences which allow sand traps to create blowouts and increase windblown sand capture.
Beach drainage Beach drainage or beach face dewatering lowers the
water table locally beneath the beach face. This causes
accretion of sand above the drainage system. Beach watertables have an important bearing on deposition/erosion across the foreshore. In one study a high watertable coincided with accelerated beach erosion, while a low watertable coincided with pronounced aggradation of the foreshore. A lower watertable (unsaturated beach face) facilitates deposition by reducing flow velocities during backwash and prolonging laminar flow. With the beach in a saturated state, backwash velocity is accelerated by the addition of groundwater seepage out of the beach within the effluent zone. However, no case studies provide indisputable evidence of positive results, although in some cases overall positive performance was reported. Long-term monitoring was not undertaken at a frequency high enough to discriminate the response to high energy erosive events. A useful side effect of the system is that collected seawater is relatively pure because of sand's filtration effect. Such water may be discharged or be used to oxygenate stagnant inland lagoons/marinas or used as feed for heat pumps, desalination plants, land-based aquaculture, aquariums or swimming pools. Beach drainage systems have been installed in many locations around the world to halt and reverse erosion trends in sand beaches. Between 1981 and 2015, twenty four beach drainage systems have been installed in Denmark, USA, UK, Japan, Spain, Sweden, France, Italy and Malaysia.
Buffer zones Coastal and estuarine ecosystems act as buffer zones against natural hazards and environmental disturbances, such as floods, cyclones, tidal surges and storms. The role they play is to "[absorb] a portion of the impact and thus [lessen] its effect on the land".
Wetlands (which include
saltwater swamps,
salt marshes, ...) and the vegetation it supports – trees, root mats, etc. – retain large amounts of water (surface water, snowmelt, rain, groundwater) and then slowly releases them back, decreasing the likeliness of floods. Mangrove forests protect coastal shorelines from tidal erosion or erosion by currents; a process that was studied after the 1999 cyclone that hit India. Villages that were surrounded with
mangrove forests encountered less damages than other villages that weren't protected by mangroves.
Costs The costs of installation and operation vary due to: • system length (non-linear cost elements) • pump flow rates (sand permeability, power costs) • soil conditions (presence of rock or impermeable strata) • discharge arrangement /filtered seawater utilization • drainage design, materials selection & installation methods • geographical considerations (location logistics) • regional economic considerations (local capabilities /costs) • study requirements /consent process. ==Monitoring ==