Deltaic lobe

Last updated February 01, 2024

A deltaic lobe is a wetland formation that forms as a river empties water and sediment into other bodies of water. As the sediment builds up from this delta, the river will break away from its single channel and the mouth will be pushed outwards, forming a deltaic lobe.^[1]

When the rate of water discharge and lobe progradation are sufficiently high, a river can form a deltaic lobe. A single deltaic lobe includes a network of shallow channels called distributaries that make up a distributary network that branches off from the mainstream of the river. These networks can be the blueprint for a future progradational deltaic lobe when the initial deltaic lobe is abandoned.^[2] As the deltaic lobe progresses, heavier and coarser sediments settle first. As heavier sediments are deposited at the top of the deltaic lobe, smaller and finer sediments get deposited out, creating the beginning of a deltaic fan. When the alluvium, the smallest sediment carried by the deltaic lobe, is deposited and new land is formed, the resulting formation is considered a delta.^[1]

Lobes are important in forming river deltas over time by amalgamation of channel avulsions.^[3] When a lobe is prograded the frequency of avulsion decreases, and the avulsion length increases relative to a non-progradational deltaic lobe. As the deltaic lobe progrades, the channel bed gradient is lowered, resulting in a sedimentary push upstream. This shifts the location of the avulsion forwards creating a completed deltaic lobe on which overlies a delta.^[1] Lobe formation is determined by a relationship between water discharge and lobe progradation. A model must take into account both factors in order to accurately predict avulsion timing and location.^[3]

Types

Wave-dominated deltaic lobes

In wave-dominated settings the number of created deltaic lobes is limited by the number of distributaries. Lobes are rarely distinguished from one another in high tide settings as tidal currents favor channel stability and suppress avulsions.^[4] The Nile, for example, is considered to be an arcuate delta because of its arc shaping. As it is waves that shape it into an arc, it also falls under the category of a wave-dominated delta.

The word delta is derived from the Greek letter delta, which, like arcuate deltas, is roughly triangular.

Tide-dominated deltaic lobes

Tide dominated deltaic lobes are defined by high levels of sediment transfer, low numbers of distributaries, and the possible creation of tidal dominated fluvial structures such as sandbars.^[5] This high level of sediment transfer can be attributed to the tidally generated water movements that control the levels of water flux on the system, and to a lesser extent the increase of river discharge and local precipitation.^[6] All created channels are widened by the incoming and outgoing tide but the water depth does not increase significantly so the tidal deltaic lobe progrades further sea-word creating multiple distributaries and a flooding effect.^[7]

One example of a tide-dominated deltaic lobe system is the Han River delta in Korea. The Han River delta is shaped by its tidal changes in the summer and winter as well as its shallow and steep basins.^[7]

Bird's-foot deltaic lobes

The Mississippi River delta (see lede image) is made up of six subdeltas, which in turn are made up of 16 individual lobes. Individual lobes in multilobe deltas can be vastly different from one another. Lobes are sequentially abandoned; the overly-extended seaward lobe silts up, and the river finds another outlet that is shorter and more direct. This sequential channel abandonment causes the deltaic plain to grow, creating a bird's foot delta composed of many deltaic lobes.^[8]

Each major deltaic lobe is composed of complex non-detrital sediments indigenous to the basin of deposition. A change in sediment supply is responsible not only for the abandonment of a deltaic lobe, but also the coastal retreat and reaccumulation of sediments over the detrital lens.

Cuspate deltaic lobes

A cuspate deltaic lobe involves the creation and subsequent abandonment of deltaic lobe cusps to create unique linear delta formations. The cuspate deltaic lobe is defined by its abrupt rate of discharge from river to body of water, and the creation of multiple cusp systems built up into separate but active distributaries.^[9]

One such example of a cuspate delta is the Tiber River delta of Italy. The river was formed first as a deltaic lobe cusp prograded from the river mouth. An abrupt southward migration of the river mouth left the first cusp abandoned and a new deltaic lobe prograded. Finally, the two distributary channels formed one deltaic formation running through the city center.^[10]

Gilbert deltaic lobes

Gilbert deltaic lobes are defined by their movement of coarse-grained materials, relatively large sizes, and steep slopes into basins.^[11] This rise in level commonly results in intensified aggradation and eventual decrease in topset slope.^[11] The most well documented example of gilbert deltaic lobes is at the gilbert delta of Lake Bonneville.^[12]

Related Research Articles

A floodplain or flood plain or bottomlands is an area of land adjacent to a river. Floodplains stretch from the banks of a river channel to the base of the enclosing valley, and experience flooding during periods of high discharge. The soils usually consist of clays, silts, sands, and gravels deposited during floods.

A river delta is a landform shaped like a triangle, created by the deposition of sediment that is carried by a river and enters slower-moving or stagnant water. This occurs at a river mouth, when it enters an ocean, sea, estuary, lake, reservoir, or another river that cannot carry away the supplied sediment. It is so named because its triangle shape resembles the uppercase Greek letter delta, Δ. The size and shape of a delta are controlled by the balance between watershed processes that supply sediment, and receiving basin processes that redistribute, sequester, and export that sediment. The size, geometry, and location of the receiving basin also plays an important role in delta evolution.

An alluvial fan is an accumulation of sediments that fans outwards from a concentrated source of sediments, such as a narrow canyon emerging from an escarpment. They are characteristic of mountainous terrain in arid to semiarid climates, but are also found in more humid environments subject to intense rainfall and in areas of modern glaciation. They range in area from less than 1 square kilometer (0.4 sq mi) to almost 20,000 square kilometers (7,700 sq mi).

Barrier islands are a coastal landform—a type of dune system and sand island—where an area of sand has been formed by wave and tidal action parallel to the mainland coast. They usually occur in chains, consisting of anything from a few islands to more than a dozen. They are subject to change during storms and other action, but absorb energy and protect the coastlines and create areas of protected waters where wetlands may flourish. A barrier chain may extend for hundreds of kilometers, with islands periodically separated by tidal inlets. The largest barrier island in the world is Padre Island of Texas, United States, at 113 miles (182 km) long. Sometimes an important inlet may close permanently, transforming an island into a peninsula, thus creating a barrier peninsula, often including a beach, barrier beach. Though many are long and narrow, the length and width of barriers and overall morphology of barrier coasts are related to parameters including tidal range, wave energy, sediment supply, sea-level trends, and basement controls. The amount of vegetation on the barrier has a large impact on the height and evolution of the island.

The Mahakam River is third longest and volume discharge river in Borneo after Kapuas River and Barito River, it is located in Kalimantan, Indonesia. It flows 980 kilometers from the district of Long Apari in the highlands of Borneo, to its mouth at the Makassar Strait.

<span class="mw-page-title-main">Tidal creek</span> Inlet or estuary that is affected by ebb and flow of ocean tides

A tidal creek or tidal channel is a narrow inlet or estuary that is affected by the ebb and flow of ocean tides. Thus, it has variable salinity and electrical conductivity over the tidal cycle, and flushes salts from inland soils. Tidal creeks are characterized by slow water velocity, resulting in buildup of fine, organic sediment in wetlands. Creeks may often be a dry to muddy channel with little or no flow at low tide, but with significant depth of water at high tide. Due to the temporal variability of water quality parameters within the tidally influenced zone, there are unique biota associated with tidal creeks which are often specialised to such zones. Nutrients and organic matter are delivered downstream to habitats normally lacking these, while the creeks also provide access to inland habitat for salt-water organisms.

The Fly River is the third longest river in the island of New Guinea, after the Sepik River and Mamberamo River, with a total length of 1,060 km (660 mi). It is the largest by volume of discharge in Oceania, the largest in the world without a single dam in its catchment, and overall the 20th-largest primary river in the world by discharge volume. It is located in the southwest of Papua New Guinea and in the South Papua province of Indonesia. It rises in the Victor Emanuel Range arm of the Star Mountains, and crosses the south-western lowlands before flowing into the Gulf of Papua in a large delta. The Fly-Strickland River system has a total length of 1,220 km (760 mi), making it the longest river system of an island in the world. The 824 km (512 mi) Strickland River is the longest and largest tributary of Fly River, making it the farthest distance source of the Fly River.

The Oak Ridges Moraine is a geological landform that runs east-west across south central Ontario, Canada. It developed about 12,000 years ago, during the Wisconsin glaciation in North America. A complex ridge of sedimentary material, the moraine is known to have partially developed under water. The Niagara Escarpment played a key role in forming the moraine in that it acted as a dam for glacial meltwater trapped between it and two ice lobes.

<span class="mw-page-title-main">Meander</span> One of a series of curves in a channel of a matured stream

A meander is one of a series of regular sinuous curves in the channel of a river or other watercourse. It is produced as a watercourse erodes the sediments of an outer, concave bank and deposits sediments on an inner, convex bank which is typically a point bar. The result of this coupled erosion and sedimentation is the formation of a sinuous course as the channel migrates back and forth across the axis of a floodplain.

A tidal river is a river whose flow and level are caused by tides. A section of a larger river affected by the tides is a tidal reach, but it may sometimes be considered a tidal river if it had been given a separate and another title name.

<span class="mw-page-title-main">River bifurcation</span> The forking of a river into its distributaries

River bifurcation occurs when a river flowing in a single channel separates into two or more separate streams which then continue downstream. Some rivers form complex networks of distributaries, typically in their deltas. If the streams eventually merge again or empty into the same body of water, then the bifurcation forms a river island.

A crevasse splay is a sedimentary fluvial deposit which forms when a stream breaks its natural or artificial levees and deposits sediment on a floodplain. A breach that forms a crevasse splay deposits sediments in similar pattern to an alluvial fan deposit. Once the levee has been breached the water flows out of its channel. As the water spreads onto the flood plain sediments will start to fall out of suspension as the water loses energy. The resulting deposition can create graded deposits similar to those found in Bouma sequences. In some cases crevasse splays can cause a river to abandon its old river channel, a process known as avulsion. Breaches that form a crevasse splay deposits occur most commonly on the outside banks of meanders where the water has the highest energy. Crevasse splay deposits can range in size. Larger deposits can be 6 m (20 ft) thick at the levee and spread 2 km (1.2 mi) wide, while smaller deposits may only be 1 cm (0.39 in) thick.

In the Earth sciences, a palaeochannel, also spelled paleochannel, is a significant length of a river or stream channel which no longer conveys fluvial discharge as part of an active fluvial system. The term palaeochannel is derived from the combination of two words, palaeo or old, and channel; i.e., a palaeochannel is an old channel. Palaeochannels may be preserved either as abandoned surface channels on the surface of river floodplains and terraces or infilled and partially or fully buried by younger sediments. The fill of a palaeochannel and its enclosing sedimentary deposits may consist of unconsolidated, semi-consolidated, or well-cemented sedimentary strata depending on the action of tectonics and diagenesis during their geologic history after deposition. The abandonment of an active fluvial channel and the resulting formation of a palaeochannel can be the result of tectonic processes, geomorphologic processes, anthropogenic activities, climatic changes, or a variable and interrelated combination of these factors.

In sedimentary geology and fluvial geomorphology, avulsion is the rapid abandonment of a river channel and the formation of a new river channel. Avulsions occur as a result of channel slopes that are much less steep than the slope that the river could travel if it took a new course.

<span class="mw-page-title-main">Bar (river morphology)</span> Elevated region of sediment in a river that has been deposited by the flow

A bar in a river is an elevated region of sediment that has been deposited by the flow. Types of bars include mid-channel bars, point bars, and mouth bars. The locations of bars are determined by the geometry of the river and the flow through it. Bars reflect sediment supply conditions, and can show where sediment supply rate is greater than the transport capacity.

A mouth bar is an element of a deltaic system, which refers to the typically mid-channel deposition of the sediment transported by the river channel at the river mouth.

An alluvial river is one in which the bed and banks are made up of mobile sediment and/or soil. Alluvial rivers are self-formed, meaning that their channels are shaped by the magnitude and frequency of the floods that they experience, and the ability of these floods to erode, deposit, and transport sediment. For this reason, alluvial rivers can assume a number of forms based on the properties of their banks; the flows they experience; the local riparian ecology; and the amount, size, and type of sediment that they carry.

A tidal prism is the volume of water in an estuary or inlet between mean high tide and mean low tide, or the volume of water leaving an estuary at ebb tide.

<span class="mw-page-title-main">Delta Field (Niger Delta)</span>

The Delta Field is located offshore from Nigeria on Oil Mining Leases (OML) 49 and 95. This is located within the Niger Delta Basin and sits in 12 feet of water. In 1965, the Delta 1 well was completed and the Delta Field opened in 1968 for production.

A hapua is a river-mouth lagoon on a mixed sand and gravel (MSG) beach, formed at the river-coast interface where a typically braided, although sometimes meandering, river interacts with a coastal environment that is significantly affected by longshore drift. The lagoons which form on the MSG coastlines are common on the east coast of the South Island of New Zealand and have long been referred to as hapua by the Māori. This classification differentiates hapua from similar lagoons located on the New Zealand coast termed waituna.

References

1 2 3 David E. Frazier. "Recent Deltaic Deposits of Mississippi River: Their Development and Chronology: ABSTRACT." AAPG Bulletin, vol. 51, 1967, doi:10.1306/5d25c219-16c1-11d7-8645000102c1865d.
↑ Delta. (October 10, 2016). In National Geographic Society. Delta
1 2 Moodie, Andrew J., et al. "Modeling Deltaic Lobe‐Building Cycles and Channel Avulsions for the Yellow River Delta, China." Journal of Geophysical Research: Earth Surface, vol. 124, no. 11, 2019, pp. 2438–2462., doi:10.1029/2019jf005220.
↑ Giosan, L., and S.L. Goodbred. "FLUVIAL ENVIRONMENTS | Deltaic Environments." Encyclopedia of Quaternary Science, 2007, pp. 704–716., doi:10.1016/b0-44-452747-8/00120-4.
↑ Fagherazzi, S. "Self-Organization of Tidal Deltas." Proceedings of the National Academy of Sciences, vol. 105, no. 48, 2008, pp. 18692–18695., doi:10.1073/pnas.0806668105.
↑ Dalrymple, Robert W., and Kyungsik Choi. "Morphologic and Facies Trends through the Fluvial–Marine Transition in Tide-Dominated Depositional Systems: A Schematic Framework for Environmental and Sequence-Stratigraphic Interpretation." Earth-Science Reviews, vol. 81, no. 3-4, 2007, pp. 135–174., doi:10.1016/j.earscirev.2006.10.002.
1 2 "The Tide-Dominated Han River Delta, Korea." 2016, doi:10.1016/c2013-0-15362-7.
↑ Charles R. Kolb, Jack R. Van Lopik. "Depositional Environments of Mississippi River Deltaic Plain--Southeastern Louisiana: ABSTRACT." AAPG Bulletin, vol. 49, 1965, doi:10.1306/a66337f6-16c0-11d7-8645000102c1865d.
↑ Arnaud-Fassetta, Gilles, et al. "The Site of Aquileia (Northeastern Italy): Example of Fluvial Geoarchaeology in a Mediterranean Deltaic Plain / Le Site D'Aquilée (Italie Nord-Orientale): Exemple De Géoarchéologie Fluviale Dans Une Plaine Deltaïque Méditerranéenne." Géomorphologie: Relief, Processus, Environnement, vol. 9, no. 4, 2003, pp. 227–245., doi:10.3406/morfo.2003.1187.
↑ Bellotti, P., et al. "The Tiber River Delta Plain (Central Italy): Coastal Evolution and Implications for the Ancient Ostia Roman Settlement." The Holocene, vol. 21, no. 7, 2011, pp. 1105–1116., doi:10.1177/0959683611400464.
1 2 Chavarrías, Víctor, et al. "A Sand‐Gravel Gilbert Delta Subject to Base Level Change." Journal of Geophysical Research: Earth Surface, vol. 123, no. 5, 2018, pp. 1160–1179., doi:10.1029/2017jf004428.
↑ "Geological and Petrophysical Characterization of the Ferron Sandstone for 3-D Simulation of a Fluvial-Deltaic Reservoir." 2001, doi:10.34191/mp-02-6.

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[auto3-1] 1 2 3 David E. Frazier. "Recent Deltaic Deposits of Mississippi River: Their Development and Chronology: ABSTRACT." AAPG Bulletin, vol. 51, 1967, doi:10.1306/5d25c219-16c1-11d7-8645000102c1865d.

[2] Delta. (October 10, 2016). In National Geographic Society. Delta

[auto-3] 1 2 Moodie, Andrew J., et al. "Modeling Deltaic Lobe‐Building Cycles and Channel Avulsions for the Yellow River Delta, China." Journal of Geophysical Research: Earth Surface, vol. 124, no. 11, 2019, pp. 2438–2462., doi:10.1029/2019jf005220.

[4] Giosan, L., and S.L. Goodbred. "FLUVIAL ENVIRONMENTS | Deltaic Environments." Encyclopedia of Quaternary Science, 2007, pp. 704–716., doi:10.1016/b0-44-452747-8/00120-4.

[5] Fagherazzi, S. "Self-Organization of Tidal Deltas." Proceedings of the National Academy of Sciences, vol. 105, no. 48, 2008, pp. 18692–18695., doi:10.1073/pnas.0806668105.

[6] Dalrymple, Robert W., and Kyungsik Choi. "Morphologic and Facies Trends through the Fluvial–Marine Transition in Tide-Dominated Depositional Systems: A Schematic Framework for Environmental and Sequence-Stratigraphic Interpretation." Earth-Science Reviews, vol. 81, no. 3-4, 2007, pp. 135–174., doi:10.1016/j.earscirev.2006.10.002.

[auto1-7] 1 2 "The Tide-Dominated Han River Delta, Korea." 2016, doi:10.1016/c2013-0-15362-7.

[8] Charles R. Kolb, Jack R. Van Lopik. "Depositional Environments of Mississippi River Deltaic Plain--Southeastern Louisiana: ABSTRACT." AAPG Bulletin, vol. 49, 1965, doi:10.1306/a66337f6-16c0-11d7-8645000102c1865d.

[9] Arnaud-Fassetta, Gilles, et al. "The Site of Aquileia (Northeastern Italy): Example of Fluvial Geoarchaeology in a Mediterranean Deltaic Plain / Le Site D'Aquilée (Italie Nord-Orientale): Exemple De Géoarchéologie Fluviale Dans Une Plaine Deltaïque Méditerranéenne." Géomorphologie: Relief, Processus, Environnement, vol. 9, no. 4, 2003, pp. 227–245., doi:10.3406/morfo.2003.1187.

[10] Bellotti, P., et al. "The Tiber River Delta Plain (Central Italy): Coastal Evolution and Implications for the Ancient Ostia Roman Settlement." The Holocene, vol. 21, no. 7, 2011, pp. 1105–1116., doi:10.1177/0959683611400464.

[auto2-11] 1 2 Chavarrías, Víctor, et al. "A Sand‐Gravel Gilbert Delta Subject to Base Level Change." Journal of Geophysical Research: Earth Surface, vol. 123, no. 5, 2018, pp. 1160–1179., doi:10.1029/2017jf004428.

[12] "Geological and Petrophysical Characterization of the Ferron Sandstone for 3-D Simulation of a Fluvial-Deltaic Reservoir." 2001, doi:10.34191/mp-02-6.

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