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Coastal plain

A coastal plain is a broad, flat or gently sloping of low-lying land adjacent to a coast, formed primarily through the deposition of unconsolidated sediments on a passive . These plains typically exhibit a subtle seaward tilt, often marked by a series of marine terraces created by fluctuating sea levels during periods of and regression, with the inland boundary defined by a where it meets more resistant upland terrain. Composed mainly of sands, clays, silts, gravels, and other soft sedimentary layers ranging from to in age, coastal plains accumulate over ancient rifted continental edges as continents drift away from diverging plate boundaries, such as during the breakup of . Coastal plains are prominent features along passive margins worldwide, including the Atlantic and Gulf coasts of , where they extend hundreds of kilometers inland and support diverse ecosystems like wetlands, estuaries, and barrier islands due to their low relief and poor drainage. Geologically, they contrast with active margins by lacking significant tectonic uplift or , instead evolving through , , and input from rivers and coastal processes. These regions are ecologically vital, hosting rich and serving as buffers against storms, but they are vulnerable to sea-level rise and human development.

Overview

Definition

A coastal plain is a flat or gently sloping landform situated immediately adjacent to a coastline, generally at elevations below 200 meters above sea level, and composed primarily of unconsolidated sediments such as sands, silts, and clays deposited through marine and fluvial processes. These sediments often range in age from the Late Cretaceous to the recent Holocene, particularly in examples like the North American coastal plains, creating a relatively young geological province characterized by low relief. Unlike the continental shelf, which represents the submerged, gently sloping underwater extension of the continental margin typically at depths less than 200 meters, a coastal plain is the emergent, counterpart above , directly interfacing with terrestrial and environments. Similarly, it differs from an , which forms from river-borne sediments in inland settings away from the and lacks significant tidal or influences, by its direct exposure to incursion, , and tidal fluctuations that shape its surface features. The term "coastal plain" originated in 19th-century geological literature, where it was first applied to describe the broad, low-elevation terrains along the U.S. Atlantic seaboard, distinguishing them from the higher, more rugged interior highlands. This nomenclature reflected early observations of sediment deposition near the coast, providing a foundational concept in American and physiographic studies.

Key Characteristics

Coastal plains are defined by their low-relief , featuring gentle slopes that typically range from 0 to 1% and elevations often below 20 meters near the , creating broad, flat expanses that extend inland from the shoreline. These landscapes commonly include dynamic coastal features such as barrier islands, which form protective chains parallel to the shore; lagoons, like the expansive and Albemarle Sounds along the U.S. Atlantic coast; and extensive marshes that fringe the inland margins. This subdued terrain results in minimal elevation changes, facilitating slow drainage and the accumulation of sedimentary layers up to several thousand meters thick in some regions. These features are prominent worldwide along passive continental margins, though characteristics vary by region. In many coastal plains, such as those in the , the soils are predominantly sandy or silty Ultisols and similar sedimentary-derived types, exhibiting high permeability that allows for rapid infiltration rates and efficient drainage in upland areas. In contrast, clay-rich variants in lower-lying zones have lower permeability, leading to water retention and periodic saturation. Hydrological processes are dominated by shallow tables, which fluctuate seasonally, and frequent flooding in estuarine and marshy sectors, influencing and nutrient cycling without significant due to the stable substrate. These characteristics often occur in tectonically stable environments, enhancing long-term landscape preservation. Coastal plains span various climates worldwide, though many lie within subtropical or temperate zones, marked by high humidity levels—often exceeding 70% annually—and warm, moist summers paired with mild winters, as seen in regions like the . Proximity to oceans exposes them to frequent storms, including tropical cyclones and hurricanes, intensified by warm sea surface temperatures that fuel convective activity. Their low topographic profile heightens vulnerability to sea-level rise, which has accelerated to approximately 4.4 millimeters per year as of the early 2020s, exacerbating tidal inundation and impacts in these areas.

Geological Formation

Primary Processes

Coastal plains often originate through erosional retreat, where tectonic uplift or exposes coastal margins to wave and current action, carving broad, low-relief platforms that later serve as bases for accumulation. During periods of relative uplift, wave erosion undercuts headlands and cliffs, retreating the shoreline inland and beveling the landscape into a near-horizontal surface known as a . Conversely, lowers the land relative to , allowing marine processes to erode elevated terrains and expand the zone of coastal planation. This erosional phase creates the foundational geometry of many coastal plains, as seen in the terraced landscapes of the , where repeated cycles of have shaped extensive lowlands. Isostatic adjustment plays a foundational role in initiating and modifying coastal plains by altering land elevation through the Earth's crustal response to loading and unloading. Post-glacial rebound, occurring after the melting of Pleistocene ice sheets, causes formerly depressed regions to uplift as the mantle flows back beneath the crust, exposing previously submerged surfaces and facilitating erosion of nascent plains. In contrast, tectonic subsidence in continental margins depresses the crust, promoting the development of subsiding basins where erosional platforms can form under ongoing marine attack. These adjustments, driven by viscous mantle flow, have been particularly influential along formerly glaciated coasts, where rebound rates can reach several millimeters per year, reshaping plain morphology over millennia. Eustatic sea-level changes, primarily driven by fluctuations in global ice volume, have profoundly influenced coastal plain formation during the Pleistocene-Holocene transition by controlling the position of erosional bases. During the , approximately 26,500 to 19,000 years ago, eustatic sea levels were about 120 meters lower than present due to vast continental ice sheets, exposing continental shelves to subaerial and river incision that preconditioned plain development. As ensued, rapid eustatic rise—averaging over 10 millimeters per year in pulses—flooded these eroded surfaces, initiating transgressive conditions that enhanced wave and created accommodation space for later deposition. These fluctuations, superimposed on isostatic effects, resulted in stair-stepped sequences marking successive highstands, which define the upper boundaries of many modern coastal plains.

Sediment Dynamics

Sediments that form coastal plains originate from multiple sources, with fluvial inputs from constituting the dominant supply, delivering approximately 90% of the total volume at rates of 1 to 10 km³ per year globally. Littoral drift, driven by wave action along the shore, contributes additional terrigenous material through of cliffs, dunes, and beaches, redistributing and gravel parallel to the coastline. Biogenic sources, including fragments from shells, reefs, and other marine organisms, supplement these inputs, particularly in tropical and subtropical settings where skeletal debris accumulates as fine to coarse sands. Transport of these sediments occurs primarily through longshore currents generated by obliquely approaching in the , which mobilize and carry material alongshore at rates dependent on , angle of incidence, and . flows play a complementary , especially in mesotidal to macrotidal environments, where ebb and flood currents redistribute finer sediments like and across nearshore and estuarine zones parallel to the . These mechanisms ensure a dynamic , with longshore dominating sandy coasts and tidal action influencing muddier, low-energy margins. Deposition patterns in coastal plains result in progradation, the seaward advance of the shoreline, at typical rates of 1 to 10 meters per year in active sedimentary systems, leading to the formation of expansive plains or elongated spits. emerge where fluvial sediments accumulate at mouths, creating lobate or bird-foot structures as coarser sands settle near the outlet and finer silts extend farther . Spits develop through longshore deposition at coastal promontories or inlets, forming narrow, recurved barriers that extend to prevailing currents before curving with wave refraction. These patterns can be modulated by relative sea-level changes, where rising levels may temporarily slow progradation by increasing accommodation space.

Classification

Tectonic Types

Coastal plains are classified according to their underlying tectonic settings, which determine their width, stability, and sediment accumulation patterns, as outlined in the plate tectonics-based framework developed by Inman and Nordstrom. This classification emphasizes the position of the continental margin relative to plate boundaries, with trailing-edge plains forming on passive margins distant from active tectonics, while collision coasts develop along more dynamic convergent or transform boundaries. Marginal sea settings, a distinct category behaving similarly to trailing-edge types due to sheltering by island arcs, can also host coastal plains but are less emphasized in primary classifications. Trailing-edge plains occur along passive margins situated on stable cratonic interiors, where the absence of significant tectonic activity promotes and the accumulation of thick sedimentary layers over geological time. These plains are characteristically broad, often extending hundreds of kilometers inland, and feature wide shelves that facilitate extensive deposition with minimal disruption from earthquakes or . In such settings, the minimal tectonic interference allows for the development of low-relief landscapes dominated by fluvial and deltaic s, resulting in sediment-rich profiles that can reach thicknesses of several kilometers. In contrast, collision coasts form along convergent or transform plate boundaries, where ongoing tectonic forces lead to narrower, more elevated, and dynamically evolving coastal features with limited coastal plains. These areas experience frequent uplift, faulting, and due to plate interactions, restricting the width of coastal plains to tens of kilometers or less and limiting preservation through tectonic deformation. The resulting plains are often steeper and more dissected, with influenced by high-energy tectonic events rather than steady accumulation. A key distinction arises between Atlantic-type and Pacific-type coastal plains, reflecting their respective tectonic histories. Atlantic-type plains, associated with trailing-edge passive margins formed by continental rifting, are generally wider and more stable, benefiting from prolonged that enhances buildup. Pacific-type plains, linked to active marginal settings with frequent or transform activity, tend to be narrower and less stable, with tectonic uplift often overriding deposition processes. This contrast underscores how rifting versus convergence influences the scale and persistence of coastal plains globally.

Morphological Variants

Coastal plains exhibit diverse morphological variants shaped by the interplay of deposition, wave action, and tidal influences, resulting in distinct surface landforms that characterize their coastal landscapes. These variants include systems, deltaic plains, and chenier plains, each reflecting specific depositional environments and energy regimes along the shoreline. Barrier island systems consist of elongated chains of sandy islands that form parallel to the , typically separated by inlets, estuaries, or passes. These islands arise from the accumulation of in shallow nearshore zones, where and currents redistribute sediments into low-lying ridges that protect back-barrier wetlands and lagoons. The morphology features dynamic barriers with beaches facing the open , overwash fans during storms, and interior dunes or marshes, adapting to fluctuating sea levels and sediment supply. Deltaic plains develop as fan-shaped expanses of at mouths, where fluvial deposits spread outward into coastal waters, forming a network of channels that branch across the plain. This results from the progradation of river-borne sediments, creating a low-gradient surface with levees, bays, and interdistributary marshes, often modified by or reworking at the margins. The overall shape emphasizes radial sediment dispersal, with the plain's breadth determined by the balance between and marine erosion. Chenier plains are characterized by linear ridges of shelly or sandy material interspersed with expansive mudflats, forming in low-energy coastal settings where fine-grained sediments dominate. These ridges, known as cheniers, emerge from episodic or deposition of coarser shells and atop prograding mud layers, creating a ridged amid otherwise flat, marshy expanses. The variant's evolution involves alternating phases of mudflat accumulation and ridge formation, influenced by subtle shifts in sediment texture and coastal energy.

Global Distribution

Major Regions

Coastal plains along the margins are among the most extensive globally, primarily due to the passive tectonic nature of these continental edges following the breakup of the supercontinent . In , the Atlantic Coastal Plain forms a broad, low-relief zone along the eastern seaboard from to , extending southward as the , characterized by thick accumulations of unconsolidated sediments derived from erosion and marine deposition. This region exemplifies a classic setting, with minimal tectonic activity allowing for stable sediment buildup over millions of years. In , the region features a similarly expansive coastal plain flanking the Fennoscandian Shield to the west, developed as the basin filled with sediments during the period, creating a coalesced lowland extending across parts of the , , and the . Along Africa's Atlantic coast, coastal plains range from narrow low-lying zones in (e.g., , ) to broader deltaic systems, such as the in covering ~70,000 km², formed by fluvial and marine sediments on passive margins since the breakup of . These Atlantic examples highlight the prevalence of wide coastal plains on passive margins, contrasting with more dynamic tectonic environments elsewhere. Coastal plains in the realm tend to be narrower and more fragmented, particularly along the active margins of , where ongoing plate convergence and limit lateral sediment spread and promote uplift or . In areas like and the Indonesian archipelago, tectonic activity associated with the convergence of the Indo-Australian, Eurasian, and Pacific plates results in confined coastal lowlands prone to rapid morphological changes. However, on passive margins, broader plains occur, such as India's Eastern Coastal Plain, extending ~1,000 km from to with widths of 100–130 km and featuring extensive river deltas of the , Godavari, Krishna, and Cauvery rivers. This tectonic regime, involving consumed plates and frequent seismicity, restricts the development of broad plains compared to passive Atlantic counterparts. Prominent coastal plains in the , such as those along 's margins and South America's Atlantic coast, bear the geological imprint of Gondwana's fragmentation around 180 million years ago, which established passive margins conducive to sediment accumulation. In , these include the relatively narrow but continuous eastern coastal plain between the and the Pacific, as well as the broader in the west, shaped by marine transgressions over ancient Gondwanan basement rocks. Along South America's eastern seaboard, particularly northeastern , low-lying plains extend inland from , formed by fluvial and marine sediments on a rifted Gondwanan margin. The shared Gondwanan heritage underscores similar depositional histories in these regions, fostering extensive sediment wedges post-breakup.

Notable Examples

The U.S. Atlantic Coastal Plain exemplifies a trailing-edge coastal plain formed along a , extending approximately 2,200 km from northward to , where Miocene sediments are prominently exposed due to differential and uplift patterns. This region features a broad, low-relief surface underlain by unconsolidated deposits that thicken seaward, illustrating the sedimentary wedge characteristic of such plains. The represents a classic deltaic coastal plain, covering about 22,000 km² and primarily formed through roughly 7,000 years of fluvial deposition by the River following post-glacial sea-level stabilization. Its arcuate shape and fertile alluvial soils highlight the morphological variant of river-dominated deltas, though rates varying from -3.9 to 2.3 mm/year (averaging -1.5 mm/year as of 2024 GNSS data), with local rates exceeding 10 mm/year in hotspots, driven by sediment compaction, groundwater extraction, and neotectonic factors, is altering its configuration. The Ganges-Brahmaputra Delta, the world's largest river delta covering approximately 105,000 km² across and , has formed over the through massive fluvial deposition by the , Brahmaputra, and Meghna rivers into the , exemplifying a vast deltaic coastal plain on a . The North German Plain demonstrates a glacially influenced coastal plain, stretching from the eastward to across a vast low-lying expanse shaped by multiple Pleistocene glaciations that deposited thick sheets and outwash plains. Subsequent , associated with eustatic sea-level rise, reworked these glacial sediments into coastal marshes and barrier systems, underscoring the interplay of ice-age legacies and post-glacial marine inundation in northern European lowlands.

Environmental and Human Aspects

Ecological Features

Coastal plains host distinct vegetation zones shaped by their proximity to marine environments and varying salinity levels. In temperate regions, salt marshes dominate low-lying areas, featuring halophytic grasses such as Spartina alterniflora (smooth cordgrass), which thrive in periodically inundated, saline soils and help stabilize sediments through extensive root systems. In tropical and subtropical coastal plains, mangrove forests form dense fringes along sheltered shorelines, with species like Rhizophora mangle (red mangrove) adapted to anaerobic muds via prop roots that facilitate oxygen uptake and provide habitat structure. Seaward dunes support pioneer grasses, including Uniola paniculata (sea oats) in the Atlantic and Gulf coasts, which trap wind-blown sand to initiate dune formation and prevent erosion. Faunal communities in coastal plains exhibit specialized adaptations to the dynamic interplay of freshwater, saltwater, and terrestrial influences, particularly at marine-terrestrial interfaces like estuaries. Migratory birds, such as shorebirds (e.g., plovers and sandpipers), rely on these plains for foraging during stopovers, utilizing nutrient-rich mudflats and marshes exposed by tides. Amphibians like the coastal green treefrog (Hyla cinerea) have evolved tolerance to brackish water, enabling reproduction in saline wetlands through physiological adjustments that maintain osmotic balance during larval stages. Estuaries serve as critical nurseries, where euryhaline species like blue crabs (Callinectes sapidus) navigate salinity gradients, supporting food webs that link marine and terrestrial realms. Coastal plains encompass hotspots characterized by elevated , particularly in isolated or relict habitats such as and pine savannas, where unique assemblages of and have persisted due to historical climatic stability. The North American Coastal Plain, for instance, harbors over 1,500 endemic vascular , representing a globally significant concentration of narrow-range . These hotspots face threats from , driven by natural barriers and anthropogenic pressures, which isolate populations and reduce in like endemic amphibians and orchids.

Socioeconomic Importance

Coastal plains, particularly river deltas, feature fertile alluvial soils that support high agricultural productivity, enabling intensive cultivation of staple crops such as in regions like the and Ganges-Brahmaputra deltas. These nutrient-rich sediments, deposited by river systems, have historically underpinned early civilizations, analogous to the where Mesopotamian societies developed advanced irrigation agriculture along the Tigris-Euphrates alluvial plains around 8000 BCE, fostering surplus production and urban growth. In modern contexts, such plains contribute significantly to global , with Asian mega-deltas alone producing over 20% of the world's output through multi-cropping systems on these fertile lands. Urban and infrastructural development thrives on coastal plains due to their flat and access to ports, leading to high population densities; for instance, more than 600 million people reside in low-elevation coastal zones (LECZ) below 10 meters, representing about 10% of the global population concentrated on these plains. This density drives economic hubs, with major cities like and situated on coastal plains, supporting industries from to via extensive port infrastructure that handles over 80% of global maritime commerce. Consequently, these areas generate substantial GDP contributions, exemplified by the Pearl River Delta's role in China's economy, where integrated urban-agricultural systems bolster regional prosperity. Coastal plains face significant vulnerabilities from erosion and sea-level rise, with average erosion rates reaching 7-15 meters per year in exposed areas like parts of the U.S. Gulf Coast, exacerbating land loss and threatening infrastructure. Global sea-level rise projections from IPCC AR6 indicate an increase of 0.28 to 1.01 meters by 2100 under various emissions scenarios, potentially leading to inundation of low-lying areas in coastal plains and deltas and displacing millions of people. Adaptation strategies, such as the Netherlands' polder system—which reclaims and protects low-lying land through dikes and drainage, safeguarding 26% of the country's territory below sea level—demonstrate effective engineering responses to mitigate flooding risks in subsiding coastal plains.