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Longshore drift

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Diagram demonstrating longshore drift
1=beach
2=sea
3=longshore current direction
4=incoming waves
5=swash
6=backwash

Longshore drift from longshore current is a geological process that consists of the transportation of sediments (clay, silt, pebbles, sand, shingle) along a coast parallel to the shoreline, which is dependent on oblique incoming wave direction. Oblique incoming wind squeezes water along the coast, and so generates a water current which moves parallel to the coast. Longshore drift is simply the sediment moved by the longshore current. This current and sediment movement occur within the surf zone.

Beach sand is also moved on such oblique wind days, due to the swash and backwash of water on the beach. Breaking surf sends water up the beach (swash) at an oblique angle and gravity then drains the water straight downslope (backwash) perpendicular to the shoreline. Thus beach sand can move downbeach in a sawtooth fashion many tens of meters (yards) per day. This process is called "beach drift" but some workers regard it as simply part of "longshore drift" because of the overall movement of sand parallel to the coast.

Longshore drift affects numerous sediment sizes as it works in slightly different ways depending on the sediment (e.g. the difference in long-shore drift of sediments from a sandy beach to that of sediments from a shingle beach). Sand is largely affected by the oscillatory force of breaking waves, the motion of sediment due to the impact of breaking waves and bed shear from long-shore current.[1] Because shingle beaches are much steeper than sandy ones, plunging breakers are more likely to form, causing the majority of long shore transport to occur in the swash zone, due to a lack of an extended surf zone.[1]

Overview

Longshore drift formulas

There are numerous calculations that take into consideration the factors that produce longshore drift. These formulations are:

  1. Bijker formula (1967, 1971)
  2. The Engelund and Hansen formula (1967)
  3. The Ackers and White formula (1973)
  4. The Bailard and Inman formula (1981)
  5. The Van Rijn formula (1984)
  6. The Watanabe formula (1992)[2]

These formulas all provide a different view into the processes that generate longshore drift. The most common factors taken into consideration in these formulas are:

Features of shoreline change

Longshore drift plays a large role in the evolution of a shoreline, as if there is a slight change of sediment supply, wind direction, or any other coastal influence longshore drift can change dramatically, affecting the formation and evolution of a beach system or profile. These changes do not occur due to one factor within the coastal system, in fact there are numerous alterations that can occur within the coastal system that may affect the distribution and impact of longshore drift. Some of these are:

  1. Geological changes, e.g. erosion, backshore changes and emergence of headlands.
  2. Change in hydrodynamic forces, e.g. change in wave diffraction in headland and offshore bank environments.
  3. Change to hydrodynamic influences, e.g. the influence of new tidal inlets and deltas on drift.
  4. Alterations of the sediment budget, e.g. switch of shorelines from drift to swash alignment, exhaustion of sediment sources.
  5. The intervention of humans, e.g. cliff protection, groynes, detached breakwaters.[1]

The sediment budget

The sediment budget takes into consideration sediment sources and sinks within a system.[3] This sediment can come from any source with examples of sources and sinks consisting of:

  • Rivers
  • Lagoons
  • Eroding land sources
  • Artificial sources e.g. nourishment
  • Artificial sinks e.g. mining/extraction
  • Offshore transport
  • Deposition of sediment on shore
  • Gullies through the land

This sediment then enters the coastal system and is transported by longshore drift. A good example of the sediment budget and longshore drift working together in the coastal system is inlet ebb-tidal shoals, which store sand that has been transported by long-shore transport.[4] As well as storing sand these systems may also transfer or by pass sand into other beach systems, therefore inlet ebb-tidal (shoal) systems provide good sources and sinks for the sediment budget.[4]

Sediment deposition throughout a shoreline profile conforms to the null point hypothesis; where gravitational and hydraulic forces determine the settling velocity of grains in a seaward fining sediment distribution. Long shore occurs in a 90 to 80 degree backwash so it would be presented as a right angle with the wave line.

Natural features

This section consists of features of longshore drift that occur on a coast where long-shore drift occurs uninterrupted by man-made structures.

Spits

Provincetown Spit, at the northern end of Cape Cod, was formed by longshore drift after the end of the last Ice age.

Spits are formed when longshore drift travels past a point (e.g. river mouth or re-entrant) where the dominant drift direction and shoreline do not veer in the same direction.[5] As well as dominant drift direction, spits are affected by the strength of wave-driven current, wave angle and the height of incoming waves.[6]

Spits are landforms that have two important features, with the first feature being the region at the up-drift end or proximal end (Hart et al., 2008). The proximal end is constantly attached to land (unless breached) and may form a slight “barrier” between the sea and an estuary or lagoon.[7] The second important spit feature is the down-drift end or distal end, which is detached from land and in some cases, may take a complex hook-shape or curve, due to the influence of varying wave directions.[7]

As an example, the New Brighton spit in Canterbury, New Zealand, was created by longshore drift of sediment from the Waimakariri River to the north.[5] This spit system is currently in equilibrium but undergoes alternate phases of deposition and erosion.

Barriers

Barrier systems are attached to the land at both the proximal and distal end and are generally widest at the down-drift end.[8] These barrier systems may enclose an estuary or lagoon system, like that of Lake Ellesmere enclosed by the Kaitorete Spit or hapua which form at river-coast interface such as at the mouth of the Rakaia River.

The Kaitorete Spit in Canterbury, New Zealand, is a barrier/spit system (which generally falls under the definition barrier, as both ends of the landform are attached to land, but has been named a spit) that has existed below Banks Peninsula for the last 8,000 years.[9] This system has undergone numerous changes and fluctuations due to avulsion of the Waimakariri River (which now flows to the north or Banks Peninsula), erosion and phases of open marine conditions.[9] The system underwent further changes c.500 year BP, when longshore drift from the eastern end of the “spit” system created the barrier, which has been retained due to ongoing longshore transport.[9]

Tidal inlets

The majority of tidal inlets on longshore drift shores accumulate sediment in flood and ebb shoals.[3] Ebb-deltas may become stunted on highly exposed shores and in smaller spaces, whereas flood deltas are likely to increase in size when space is available in a bay or lagoon system.[3] Tidal inlets can act as sinks and sources for large amounts of material, which therefore impacts on adjacent parts of the coastline.[10]

The structuring of tidal inlets is also important for longshore drift as if an inlet is unstructured sediment may by pass the inlet and form bars at the down-drift part of the coast.[10] Although this may also depend on the inlet size, delta morphology, sediment rate and by passing mechanism.[3] Channel location variance and amount may also influence the impact of long shore drift on a tidal inlet as well.

For example, the Arcachon lagoon is a tidal inlet system in South west France, which provides large sources and sinks for longshore drift sediments. The impact of longshore drift sediments on this inlet system is highly influenced by the variation in the number of lagoon entrances and the location of these entrances.[10] Any change in these factors can cause severe down-drift erosion or down-drift accretion of large swash bars.[10]

Human influences

This section consists of long-shore drift features that occur unnaturally and in some cases (e.g. groynes, detached breakwaters) have been constructed to enhance the effects of longshore drift on the coastline but in other cases have a negative impact on long-shore drift (ports and harbours).

Groynes

Timber groyne from Swanage Bay, UK

Groynes are shore protection structures, placed at equal intervals along the coastline in order to stop coastal erosion and generally cross the intertidal zone.[1] Due to this, groyne structures are usually used on shores with low net and high annual longshore drift in order to retain the sediments lost in storm surges and further down the coast.[1]

There are numerous variations to groyne designs with the three most common designs consisting of:

  1. zig-zag groynes, which dissipate the destructive flows that form in wave-induced currents or in breaking waves.
  2. T-head groynes, which reduce wave height through wave diffraction.
  3. ‘Y’ head, a fish-tail groyne system.[1]

Artificial headlands

Artificial headlands are also shore protection structures, which are created in order to provide a certain amount of protection to beaches or bays.[1] Although the creation of headlands involves accretion of sediments on the up-drift side of the headland and moderate erosion of the down-drift end of the headland, this is undertaken in order to design a stabilised system that allows material to accumulate in beaches further along the shore.[1]

Artificial headlands can occur due to natural accumulation or also through artificial nourishment.

Picture showing the use of artificial headlands and detached breakwaters in a coastal system

Detached breakwaters

Detached breakwaters are shore protection structures, created to build up sandy material in order to accommodate drawdown in storm conditions.[1] In order to accommodate drawdown in storm conditions detached breakwaters have no connection to the shoreline, which lets currents and sediment pass between the breakwater and the shore.[1] This then forms a region of reduced wave energy, which encourages the deposition of sand on the lee side of the structure.[1]

Detached breakwaters are generally used in the same way as groynes, to build up the volume of material between the coast and the breakwater structure in order to accommodate storm surges.[1]

Ports and harbours

The creation of ports and harbours throughout the world can seriously impact on the natural course of longshore drift. Not only do ports and harbours pose a threat to longshore drift in the short term, they also pose a threat to shoreline evolution.[1] The major influence, which the creation of a port or harbour can have on longshore drift, is the alteration of sedimentation patterns, which in turn may lead to accretion and/or erosion of a beach or coastal system.[1]

As an example, the creation of a port in Timaru, New Zealand in the late 19th century led to a significant change in the longshore drift along the South Canterbury coastline.[5] Instead of longshore drift transporting sediment north up the coast towards the Waimataitai lagoon, the creation of the port blocked the drift of these (coarse) sediments and instead caused them to accrete to the south of the port at South beach in Timaru.[5] The accretion of this sediment to the south, therefore meant a lack of sediment being deposited on the coast near the Waimataitai lagoon (to the north of the port), which led to the loss of the barrier enclosing the lagoon in the 1930s and then shortly after, the loss of the lagoon itself.[5] As with the Waimataitai lagoon, the Washdyke Lagoon, which currently lies to the north of the Timaru port, is undergoing erosion and may eventually breach, causing loss of another lagoon environment.

See also

References

Citations

  1. ^ a b c d e f g h i j k l m n Reeve et al., 2004
  2. ^ a b Integrated Publishing. "The Bijker formula". Tpub.com. Retrieved 2012-07-01.
  3. ^ a b c d Brunn, 2005
  4. ^ a b Brunn, 2005, Michel and Howa, 1997
  5. ^ a b c d e Hart et al., 2008
  6. ^ IPetersen et al., 2008
  7. ^ a b Hart et al., 2008, Petersen et al., 2008
  8. ^ Kirk and Lauder, 2000
  9. ^ a b c Soons et al., 1997
  10. ^ a b c d Michel and Howa, 1997

Books

  • Brunn, P.(ed) (2005). Port and coastal engineering developments in Science and technology. South Carolina: P.Brunn. {{cite book}}: |first= has generic name (help)
  • Hart, D.E; Marsden, I; Francis, M (2008). "Chapter 20: Coastal systems". In Winterbourne, M; Knox, G.A.; Marsden, I.D.; Burrows, C (eds.). Natural history of Canterbury (3rd ed.). Canterbury University Press. pp. 653–684.
  • Reeve, D; Chadwick, A; Fleming, C (2004). Coastal engineering-processes, theory and design practice. New York: Spon Press.

Journal articles

  • Kirk, R.M; Lauder, G.A (2000). "Significant coastal lagoon systems in the South Island, New Zealand". Science for Conservation. DOC 46p: 13–24.
  • Michel, D; Howa, H.L (1997). "Morphodynamic behaviour of a tidal inlet system in a mixed-energy environment". Physics and Chemistry of the Earth. 22 (3–4): 339–343. doi:10.1016/s0079-1946(97)00155-9.
  • Peterson, D; Deigaard, R; Fredsoe, J (July 2008). "Modelling the morphology of sandy spits". Coastal Engineering. 55 (7–8): 671–684. doi:10.1016/j.coastaleng.2007.11.009.
  • Soons, J.M; Schulmeister, J; Holt, S (April 1997). "The Holocene evolution of a well nourished gravelly barrier and lagoon complex, Kaitorete "Spit", Canterbury, New Zealand". Marine Geology. 26 (1–2): 69–90. doi:10.1016/S0025-3227(97)00003-0.