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Semi-protected edit request on 29 May 2020

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Please apply the following two changes:

Please add a new subheading as the item 4.3 and the TOC (table of content) would look as follows.

4. Erosion and accretion
4.1 Causes and effect edit-2: insert this as new heading and further rightward indent the subheadings.
4.1.1 Natural erosion and accretion edit-2: rightward indent by adding one extra "=" in heading prefix and suffix. Repeat this for all he subsequent subheadings in TOC item 4.1
4.1.1.1 Causes
4.1.1.2 Effects on flora
4.1.2.3 Effects on flora
.
. etc

4.1.2 Manmade erosion and accretion
4.1.2.1 Destruction of flora
. . etc

4.3 Beach creation and maintenance techniques edit-3: insert this as new heading and further rightward indent the subheadings. copy paste the rest of the content below.

Extended content

Beach creation and maintenance techniques

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Coastal management

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Coastal and oceanic landforms.
Five general coastal planning approaches.
Sea wall Oosterscheldekering in Netherlands.
Stone Seawall with walkway, stablized with mud revetment stablized with grass, with stone and gravel riprap armament at the base.
Series of cost effective groynes made of wood.
"Headland groyne" with wood log breakwater and stone filled wooden groyne, an easy to build cost effective option comprised of cheap and native materials.
"Headland groyne" at East Coast Beach in Singapore is comprised of breakwater parallel to shore and connected to shore by a vertical groyne. Higher mainland is fortified with a low rise mud seawall which has been further stablized by planting grass and trees.
Groyne at Mundesley, Norfolk, UK.

Integrated coastal zone management minimizes the negative human impacts on coasts, enhances coastal defense, mitigates the risk associated with the sea level rise and other natural hazards.

The beach erosion is a type of bioerosion which alters the coastal geography through beach morphodynamics. There are numerous incidences of modern recession of beaches, mainly due to the longshore drift and coastal development hazards related to human activities.

Solutions range from "do nothing" to "Move beach seaward" approach which uses the elements of hard and soft engineering. The interventionist methods, such as "Move beach seaward", combine the hard engineering methods such as constructing structures (accropodes) with the soft engineering methods such as sand dune stabilization. These intervention are aimed at prevention of beach erosion caused by longshore drift and coastal development hazards, as well as facilitation of beach evolution and expansion.

Planning approaches

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Five generic planning approaches involved in coastal defense are:[1]

  • Abandonment of shore: do nothing, let the natural process takeover.
  • Managed retreat, also called realignment.
  • Hold the shoreline: by using shoreline hardening techniques to create permanent concrete and rock constructions such as groynes.
  • Move beach seaward: by using hard and soft intervention techniques usually in areas of high economic significance.
  • Limited intervention: usually in areas of low economic significance, often includes the succession of haloseres, including salt marshes and sand dunes.

Coastal engineering

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Two coastal engineering techniques are: hard and soft engineering methods.

Hard engineering methods
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Hard engineering methods are also called "Structural methods". "move towards the sea" beach accretion can be facilitated by the four main type of hard engineering structures, namely seawall, revetment, groyne or breakwater. Most commonly used hard structures are seawall and series of "headland groyne" (breakwater connected to the shore with groyne).

  • Four main types of structures or accropodes:
    • Seawalls: 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 or concrete objects such as Tetrapods or Xblocs with flights of steps for beach access. Seawall at Cronulla beacch, NSW,[2] for example, uses concrete wall.
    • Groynes: are the walls perpendicular to the coastline. Groynes are generally placed in series and the areas between groups of groynes are called groyne fields. To directs the sand towards the shore targeted for sand accumulation, a shorter groyne turned slightly towards downdrift side of the beach is deployed at updrift end of the beach, a longer groyne at the downdrift end of the beach is deployed, a series of groyne are deployed between the two ends. Groynes are often made of gabion, 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. Groynes are cost-effective, require little maintenance and are one of the most common defences.[3]
      • Headland groyne or Bulkhead breakwater: When groyne is built to attach a breakwater to shore, the resulting T-structure is called "headland breakwater", "headland groyne", "bulkhead groyne" or "bulkhead breakwater". Use of groynes and headland groyne, accumulates the sand across the beach but it tend to deplete the sand faster from the downdrift end of the beach. This can be mitigated and sand could be accumulated at the downdrift end of the beach also. This is achieved by having a longer "groyne" or "headland groyne" at the end of downdrift side of the beach. To enhance the sand accumulation, this "headland groyne" could have another series of smaller "headland groyne" jutting out of it pointing towards updrift end of the beach in a way that the smaller "headland groyne" are parallel to the shore and perpendicular to main "headland groyne". This will facilitate gradual natural creation of ayre (sand or gravel filled beach). If there is a near shore island near the downdrift end of the beach and "headland groyne", then this could be turned into a cuspate foreland headland with the use of the gradual natural creation of ayre (gravel filled beach). Main "headland groyne" at the end of downdrift could be further stablizied by a hard engineered detention basin and grassy mangrove salt marsh. Salt marsh could be created with the use of soft engineering approach, such as lose stone sills, while leaving a whole in the sill for a seawater channel. Seawater channel could be a cemented open channel or a pipe buried under the beach. This marsh could be designed to taper into a hard engineered sandy beach. Having inland saltwater marsh between the beach and mainland will lower the cost by eliminating the need for filling up the marshy area with the sand, and the mangroves and grasses in the marsh will facilitate gradual built up of sediments.
    • Breakwater: also called "offshore breakwater", are offshore structure constructed parallel to the shore to alter wave direction and tide energy. The waves break further offshore and therefore lose erosive power. This leads to formation of wider beaches, which further absorb wave energy. A series of of breakwater is often deployed across the beach shore.
    • 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. Unless other mthods are used in combination, surf progressively erodes and destroys the revetment which requires ongoing maintenance.
  • other types of structures used are:
    • Rock armour: also called riprap, is basement placed at the sea edge using local material. This could be the protruding foot of a seawall or revetment to reduce maintenance of those. Longshore drift is not hindered.
    • Cliff stabilization: can be accomplished through drainage of excess rainwater of through terracing, planting and wiring to hold cliffs in place.
    • Floodgates: 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.
Tetrapods along the Marine Drive, Mumbai, India.
Gabion, welded wiremesh filled with stone, could be used to construct seawalls, groyne, rivetment, riprap/armour.
  • Construction elements: these can be incorporated in any of the above structures, either as core element or as a supplementary element to enhance to reduce the cost and maintenance of main structural elements.
    • Concrete objects: are complex reinforced concrete objects, such as A-jack, Akmon, Dolos, Honeycomb sea wall (Seabees), Tetrapod and Xbloc. Simple concrete blocks have been replaced by these complex concrete objects because these objects more resistant to wave action and requires less concrete to produce a superior result. These could be used to build seawalls, groyne, breakwater, and other structures including residential buildings. Tetrapod used at Marine Drive, Mumbai are an example of complex concrete objects.
    • 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.
Soft engineering methods
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Soft engineering uses a “soft” (non-permanent) structure by creating a larger sand reservoir, pushing the shoreline seaward. It gained popularity because it preserved beach resources and avoided the negative effects of hard structures.

  • Managed retreat: the shoreline is left to erode, while relocating buildings and infrastructure further inland.
  • Beach evolution: also called "beach replenishment" or "beach nourishment", it 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. Without the groynes or scheme requires repeated applications on an annual or multi-year cycle. Beach nourishment can be used in combination with seaward curving halfmoon shaped "headland breakwater" structure, this combining the benefits of breakwater and gryone structures.
  • Sand dune stabilization: protect beaches by catching windblown sand, increasing natural beach formation. Fences can allow sand traps to create blowouts and increase windblown sand capture. Plants such as Ammophila (Marram grass) can bind the sediment.
  • Beach drainage: beach face dewatering lowers the water table locally beneath the beach face. This causes accretion of sand above the drainage system.[4]

Cost factors and considerations: the costs of installation, operation and maintenance vary due to:

  • system length (non-linear cost elements)
  • 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, availability of local material and native skilled workforce)
  • study requirements /consent process.

An example

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Salt marsh during low tide, mean low tide, high tide and very high tide (spring tide).
Above and below water view at the edge of the shore.
A series of trellises forms the wall of a garden room.
Creeping groundsel growing on a wooden trellis in Italy.
Casa Redonda, one of five nipa houses built by the Philippine national hero José Rizal during his exile in Dapitan.[5]
The raised bale houses of the Ifugao people.[6]

This Integrated coastal zone management example is based on the "move beach seaward" general planning approach which involves both hard and soft engineering methods. This scenario minimizes the maintenance effort and cost by making optimal use of the coastal geography by incorporating natural costal geographical features in the engineering design. The cost is kept low by the use of easily available free or cost-effective local material, use of which is already known to or easily acquired by the local workforce. This solution entails beach nourishment (creating recreational area by filling with sand), and further beach expansion and prevention of beach erosion caused by longshore drift and coastal development hazards. The design makes use of a shorter groyne slightly inclined toward the beach in the same direction as downdrift, with a series of "headland groyne" perpendicular to the shore, and a longer "headland groyne" at the end of downdrift side of the beach with smaller "headland groyne" perpendicular to it facing the updrift end of the beach.

This example of tropical setting, part of the sea could be reclaimed by building a seawall with revetment (slope) fortified with armament of honeycomb seebee made of concrete with hexagonal holes, parts of seawall could be made of gabion. Seawall will sit[7] over gravel or rock. Seawall could be a mix of vertical structures in the areas where more space is needed and tapering revetments (slope) as aesthetic landscaping feature. Revetments could be made of locally available material. Different parts of reventment could have different material and design, such as gabion (welded wire mesh filled with stone, gravel and wood) and honeycomb seebee (made of concrete with hexagonal holes). Honeycomb seebee or gabion could be used in the downdrift areas, though wood groyne would be the cheapest option such as used at Mundesley. Other areas of seawall and revetment could be a mix of cemented low walls, gabion, riprap made of gravel or sand bags. Parts of seawall and revetment could be left exposed especially those made of decorative gabion, and others parts could be covered with low or mid level native plants. Seawall will sit[8] over gravel or rock base which could be wider than the seawall so that it also acts as the riprap armament.

Reclaimed area could be filled with the sand and stablized by aesthetic landscaping by growing native trees and plants. A dense layer of native tropical trees could be planted at the mainland side of the reclaimed land with due consideration to the height of the trees that they do not block the view of any construction such as resort or beach house. Reclaimed area would enhance the economical value by creating a sand filled safe recreation area which might house sunbathing areas and inland freshwater or seawater wading pool or lagoon surrounded by bars, restaurants, water sports, etc. Restaurants could have retractable-canopied areas set closer to the seawall greenified with tapering layers of evergreen native tropical plants. Bars could be open air, portable or canopied (thatched roof nipa hut and trellis of native material, pergola or beach parasol) bars with pool and beach seating. Seating could be relaxing-and-sprawling reclined futon type, sunken sand pits, sand filled bean bags on the beach, locally made designer stools/chairs and tables made of native eco-friendly natural material such as bamboo, aged rustic driftwood and abundant low weathering native wood.

58.182.176.169 (talk) 17:24, 29 May 2020 (UTC)[reply]

 Not done for now: please establish a consensus for this alteration before using the {{edit semi-protected}} template. A change this major needs to have consensus. I will place it in the appropriate section and provide a link to it. The venue for the consensus is at Wikipedia_talk:WikiProject_Travel_and_Tourism#Consensus_Needed ~ Galendalia Talk to me CVU Graduate 19:15, 5 June 2020 (UTC)[reply]

References

  1. ^ "Shoreline Management Guide".
  2. ^ Armour Units – Random Mass or Disciplined Array, – C.T.Brown ASCE Coastal Structures Specialty Conference, Washington, March 1979; The Design & Construction of Prince St. Seawall, Cronulla, EHW Hirst & D.N.Foster – 8th CCOE, Nov 1987, Launceston, Tasmania
  3. ^ "£47.3m project to protect Bournemouth's beaches from erosion over next 100 years".
  4. ^ [1]
  5. ^ "Rizal Shrine Dapitan". National Historical Commission. Retrieved 9 November 2014.
  6. ^ Sato, Koji (1991). "Menghuni Lumbung: Beberapa Pertimbangan Mengenai Asal-Usul Konstruksi Rumah Panggung di Kepulauan Pasifik". Antropologi Indonesia. 49: 31–47.
  7. ^ Allen, Richard Thomas Lingen, Concrete in Coastal Structures, page 47
  8. ^ Allen, Richard Thomas Lingen, Concrete in Coastal Structures, page 47