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Pediplain

A pediplain is an extensive, low-relief erosion surface formed by the coalescence of multiple pediments—gently sloping erosional aprons at the base of retreating scarps—primarily through processes of parallel scarp retreat and pedimentation in arid or semi-arid climates. These landforms result from prolonged fluvial and weathering action, where slopes recede uniformly while debris is efficiently removed by sheetwash and episodic floods, often leaving residual hills or inselbergs as isolated features. Pediplains are characterized by their broad, nearly flat to gently undulating topography, typically covered by a thin veneer of alluvium or desert pavement, and they represent a stage of landscape evolution under tectonic stability and limited vegetation cover. The theory of pediplain formation, known as pediplanation, was pioneered by geologist Lester Charles King in his 1942 book South African Scenery, as a challenge to Davis's humid-climate-focused model. King argued that pediplanation operates globally wherever running water dominates erosion, involving the parallel retreat of escarpments that maintain their profile while expanding basal pediments, ultimately merging into vast plains over multiple cycles of uplift and erosion. This model emphasizes arid processes like scarp backwearing rather than downwearing, with caprocks such as dolerite sills protecting summits and facilitating the development of mesas and buttes. King's ideas gained traction in interpreting African landscapes but faced criticism for oversimplifying climatic influences and the linkage between pedimentation and scarp retreat, though they remain influential in understanding polycyclic terrain. Notable examples include the Atacama Pediplain in northern , a composite surface spanning over 12,000 km² formed episodically since the (~20 Ma), reflecting interactions between Andean uplift, hyperarid conditions, and alluvial aggradation-degradation cycles. In , pediplains are prominent in the Karoo Basin and , where they form part of the African Surface Complex, often stabilized by duricrusts like silcrete and calcrete that preserve paleosurfaces amid tectonic quiescence. These features serve as markers of long-term geomorphic stability, with incision by rivers like the Salado indicating subsequent rejuvenation phases tied to climatic shifts and base-level changes.

Overview

Definition

A pediplain is an extensive, low-relief erosion surface formed by the coalescence of multiple pediments, creating a broad, relatively flat expanse of rock that dominates arid and semi-arid landscapes. This arises primarily through the coalescence of multiple pediments via parallel scarp retreat and basal lateral , resulting in a regionally subdued without complete base-leveling to a single datum. Key physical attributes of a pediplain include its gently undulating , marked by subtle convexo-concave profiles from the integrated , and the presence of residual hills or inselbergs that protrude as isolated remnants of pre-existing highlands. These features highlight the process's emphasis on parallel scarp retreat and minimal vertical incision, preserving structural elements while extending the plain laterally over large areas. The formation process, termed pediplanation, entails the gradual expansion of surfaces through the backwearing of escarpments and the extension of pediment aprons by lateral , ultimately yielding a mature plain with low gradients and broad, shallow concavities. Pediments serve as the foundational components in this , their merging transforming fragmented slopes into a cohesive, low-relief .

Etymology

The term "pediplain" originates from the combination of "pedi," derived from the Latin pes (genitive pedis), meaning "foot," and "plain," underscoring the landform's development at the foundational, basal zones of escarpments analogous to the "foot" of a . This nomenclature highlights the basal nature of the erosion surface, where individual pediments coalesce to form a broad, low-relief expanse. The genitive form pedis in particular emphasizes the landform's inherent connection to the lower, supportive elements of geomorphic structures, distinguishing pediplains as products of lateral at bases rather than elevated or humidity-influenced surfaces. Coined specifically to denote these coalescence-driven plains at the base of s, the term was introduced by geologists John H. Maxson and George H. Anderson in their 1935 paper on cycle terminology, providing a precise descriptor for arid and semi-arid features. This etymological choice reflects the pediplain's role as a "foothold" surface in geomorphic evolution, separate from higher-standing or fluvial-dominated plains.

Geological Formation

Pediments and Pediplanation

Pediments are gently sloping, low-relief erosion surfaces that develop at the bases of ranges or retreating scarps, often mantled with a thin layer of such as or . These surfaces form a transitional zone between uplands undergoing degradation and adjacent lowlands at base level, typically exhibiting slopes of 1° to 5° and extending laterally for several kilometers. The mantle protects the underlying from further while allowing the surface to maintain its smooth, planar character. Pediplanation refers to the erosional process by which multiple pediments coalesce laterally to form extensive, low-relief plains known as pediplains, achieved primarily through parallel retreat of scarps without deep incision into the landscape. In this mechanism, scarps erode backward uniformly, preserving their angle and form as they recede, while the pediments at their bases expand outward and merge with neighboring ones, gradually enveloping residual hills or inselbergs. This backwearing process results in widespread flattening over large areas, often spanning hundreds of kilometers, as the advancing pediments integrate into a continuous erosion surface. The primary mechanisms driving pediment development and pediplanation involve basal and sheetwash . Basal occurs where subsurface and moisture concentrate at the scarp base, undermining the slope and causing rockfalls or slumping that extend the upslope. Concurrently, sheetwash—broad, shallow overland flow during infrequent high-intensity rainfall—transports weathered debris across the surface, smoothing it and preventing formation while depositing protective . Together, these processes enable pediments to prograde outward from retreating scarps, facilitating their lateral coalescence into a unified pediplain with minimal vertical lowering.

Role of Climate

Pediplains predominantly form in arid and semi-arid regions, where limited rainfall restricts vertical incision by streams and promotes lateral erosion across broad surfaces. In these environments, sparse and minimal allow for the efficient expansion of pediments through scarp retreat, leading to the coalescence into low-relief plains. This climatic regime favors the development of pediplains over other landforms, as persistent dryness minimizes the downcutting that would otherwise fragment the surface. Low annual rates, typically less than 500 mm/year, are crucial for pediplain evolution, as they result in infrequent but intense episodic events like flash floods that facilitate sheetflow and the removal of debris from surfaces. These conditions enable widespread lateral planation, where flows spread thinly over large areas rather than concentrating in deep channels, thereby expanding the gently sloping exposures characteristic of pediplains. In contrast, higher rainfall intensities in more humid settings would accelerate vertical , hindering the preservation of these extensive low-gradient features. Alternations between arid and humid climatic phases significantly influence pediplain dynamics, with humid intervals often causing through increased stream incision or burial under weathered and sediments. However, sustained dry conditions are essential for the long-term preservation of the low-relief pediplain surface, as they limit ongoing and maintain the of the erosional plain against renewed uplift or climatic shifts. Such preservation is evident in ancient pediplains, where prolonged has protected these landforms for millions of years despite periodic wetter episodes.

Theoretical Foundations

Development by L.C. King

Lester Charles King introduced the concept of the pediplain and the process of pediplanation in his 1942 book South African Scenery, presenting it as the primary mechanism for landscape evolution in . In this work, King described pediplanation as involving the parallel retreat of escarpments, leading to the coalescence of pediments into broad, low-relief surfaces characteristic of the region's . His formulation built briefly on earlier ideas of slope retreat but emphasized their application to African terrains through direct field observations. King's model highlighted multiple cycles of scarp retreat and pediplain development spanning geological time, with each cycle producing successive erosion surfaces that could be preserved and later exhumed. He rejected assumptions of uniform uplift inherent in other geomorphic theories, instead proposing that isostatic adjustments following played a more significant role in landscape modification. This cyclic approach allowed for the integration of diverse landforms, such as inselbergs and residual hills, into a cohesive evolutionary . Central to King's argument was the assertion that pediplains constitute tangible, observable features across , formed through ongoing fluvial processes rather than abstract ideals. He contrasted these real-world surfaces with peneplains, which he viewed as largely theoretical constructs unlikely to form under the dynamic conditions prevalent in southern African landscapes. By grounding his theory in from the continent, King positioned pediplanation as a practical alternative for interpreting arid and semi-arid patterns.

Relation to Penck's Theory

The pediplain concept originates as an extension of Walther Penck's 1924 theory of slope evolution, which emphasized parallel retreat of s under varying rates of uplift and . Penck described how escarpments migrate backward without steepening, driven by concentrated at their bases, thereby forming gently sloping pediments that extend from the slope foot. This process maintains slope angles while progressively reducing relief through backwearing rather than downwearing. Penck further delineated slope phases as "waxing" (convex-upward profiles where uplift outpaces , leading to increasing ) and "waning" (concave-upward profiles where dominates, resulting in decreasing and pediment development). These phases reflect a between tectonic forces and erosional processes, with emerging during waning stages as recede parallel to their original form. L.C. King adopted and expanded this framework in his 1953 analysis, applying it to explain pediplain formation under conditions of tectonic stability, where repeated cycles of scarp retreat generate coalescing . While Penck focused primarily on isolated slope dynamics and localized landform evolution, King's pediplain model emphasizes the widespread lateral coalescence of multiple pediments into extensive, low-relief plains across stable cratons, particularly in arid to semi-arid climates. This adaptation integrates Penck's parallel retreat with broader landscape cycles, highlighting how waning slopes contribute to regional planation without requiring uniform downcutting.

Distinctions from Similar Landforms

Pediplain vs. Peneplain

The pediplain is a characterized by the coalescence of pediments formed primarily through lateral scarp retreat, a process where steep escarpments erode backward parallel to themselves in arid or semi-arid environments, resulting in broad, low-relief surfaces punctuated by steeper residual hills such as bornhardts or koppies, with minimal fluvial incision due to limited stream downcutting. This mechanism, emphasized by L.C. King, contrasts sharply with the , a concept introduced by as the end product of his geographical in humid climates, where prolonged and fluvial action lead to decline—gradual reduction in gradient through parallel downwasting—producing a gently rolling, subdued lowland of near-baselevel relief with faint structural influences. A fundamental distinction lies in the erosional dynamics and topographic outcomes: pediplains develop via headward extension of pediments with sparse, shallow networks owing to sheetwash dominance and , yielding a of abrupt hill-slope contrasts and limited incision, whereas peneplains arise from integrated fluvial systems that incise and bevel the terrain evenly, hypothetically forming an extensive plain with monadnocks but rarely observed intact due to the idealized baselevel attainment required. dismissed peneplains as largely imaginary constructs unattainable in real s, arguing instead that observed planation surfaces worldwide align better with pediplanation processes.

Pediplain vs. Etchplain

Pediplains form primarily through mechanical erosion processes, involving physical and runoff that facilitate the lateral retreat of slopes, resulting in rock-cut surfaces characterized by thin cover. This produces extensive plains where is often exposed, with steeper margins adjacent to residual hills. In contrast, etchplains develop in humid tropical environments via deep chemical weathering, known as , which dissolves and alters to form thick layers, often capped by . The process involves subsurface decomposition followed by the stripping of this weathered mantle, yielding subdued, mantled plains with low relief and minimal exposed until later erosion stages. The key distinction lies in the dominance of erosion types and resultant landform features: pediplains exhibit mechanical dominance with thin soils and prominent bedrock outcrops, favoring semi-arid climates as noted in broader climatic roles, whereas etchplains reflect chemical processes with thick soil profiles requiring subsequent stripping for plain exposure.

Global Examples

African Pediplains

hosts some of the most extensive and well-studied pediplains, where the landform concept was first extensively developed through observations of arid and semi-arid landscapes. These surfaces, often characterized by coalesced pediments and scattered , reflect prolonged scarp retreat and erosion under variable climatic conditions, primarily since the era. In , pediplains form broad, low-elevation surfaces along the Great , approximately 200 km inland from coast, separating the coastal from the elevated . These pediplains resulted from the progressive retreat of the escarpment, with significant occurring during the to epochs, driven by post-rift uplift and fluvial erosion. Prominent , such as the Brandberg Massif, rise sharply from these plains as resistant intrusions, exemplifying the dissection and isolation of harder rock masses amid the surrounding beveling. The Brandberg, reaching over 2,500 meters, stands as a classic example of an inselberg protruding through the pediplain, highlighting the selective erosion processes that shape these landscapes. The Oudalan Pediplain in northern represents a semi-arid example of pediplain development in the , forming a low-relief plain spanning between towns like Gorom-Gorom and Oursi. This surface, at elevations typically below 300 meters, consists of coalesced pediments developed on lateritic soils under seasonal rainfall regimes of 200-600 mm annually, where episodic fluvial activity dissects the plain into shallow valleys. The coalescence of these pediments exemplifies pediplanation in semi-arid environments, with ancient, vast pediplains interrupted by temporary rivers that mobilize sediments during wet seasons, contributing to the overall smoothing of the terrain. In , pediplains are prominent in the and regions, where multiple levels of planation surfaces record episodic uplift and erosion from the to the . The , an elevated interior plateau at 1,000-1,600 meters, features a mature pediplain known as the African Surface, formed through scarp retreat following breakup, with remnants dating to the late at around 500-600 meters before subsequent uplift. In the Basin, pediplains overlay sedimentary sequences, displaying stepped profiles from ancient levels () to more recent surfaces, often capped by dolerite sills and dotted with inselbergs. These features were central to L.C. King's field observations in the mid-20th century, which emphasized the cyclic retreat of scarps to produce these extensive, low-gradient plains across .

Examples from Other Continents

In , pediplains are exemplified by the mantled pediments of the arid interior, particularly in , where etch-derived surfaces coalesce to form broad, low-relief plains lacking prominent backing scarps. These features, often associated with landscapes, meet modern criteria for pediplains through the integration of pedimented zones and alluviated plains under arid conditions. Classic examples include the Barrier and pediplains in eastern , where extensive pediment coalescence has produced nearly flat surfaces over large areas, reflecting prolonged in semi-arid environments. On the , pediplain development is evident in the plains of , such as those in , where denudational processes have shaped low-relief surfaces with variable soil cover through the coalescence of pediments in the semi-arid margins of the . These areas feature residual hills amid the flattened terrain, resulting from extended etching and stripping of weathered . Similarly, the pediplain along the southwestern Deccan coast illustrates mid- to late-Tertiary pedimentation, with low-lying, lateritized surfaces formed by eastward recession of escarpments under semi-arid climates, incorporating residual uplands. In , pediplain-like surfaces occur in the , notably in the , where bajadas—coalesced alluvial fans along mountain fronts—overlay erosional pediments to create extensive, gently sloping plains. For instance, pediments in the Usery Mountains region demonstrate rapid replanation over glacial-interglacial cycles, forming near-planar bedrock surfaces through and tributary capture, though these are often viewed as incomplete pediplains due to ongoing base-level adjustments.

Modern Perspectives and Debates

Criteria for Identification

Pediplains are primarily identified through their characteristic low-relief , typically exhibiting elevations varying by less than 100 meters across extensive areas, which reflects prolonged scarp retreat and pediment coalescence under arid to semi-arid conditions. A defining feature is the presence of merged forming a broad, gently sloping surface, often accompanied by backing scarps that may be subdued or eroded but still discernible as remnants of retreating cliffs. Inselbergs, or isolated residual hills, further indicate the parallel retreat of these scarps, as they represent un-eroded portions of the original upland amid the surrounding plain. These elements collectively distinguish pediplains as products of lateral rather than vertical incision. Field-based identification relies on several observable indicators that underscore the minimal post-formation alteration of the surface. Thin layers, often only a few meters thick, overlie the , signaling limited development and ongoing exposure to processes. Granitic profiles are common, featuring corestones and grus formation due to the exfoliation and granular disintegration typical in dry climates. Additionally, the of deep fluvial valleys points to subdued stream incision, with drainage networks dominated by shallow, braided channels rather than entrenched gorges. To confirm the antiquity and stability of these features, techniques, such as measuring ^10Be concentrations in quartz-bearing rocks, provide quantitative estimates of long-term rates, often revealing values below 10 meters per million years that align with the slow of pediplains. Distinguishing true pediplains from other low-relief landforms presents significant challenges, especially in cases where the surface has been buried beneath alluvial or aeolian deposits or dissected by tectonic uplift and renewed erosion. Buried pediplains may be inferred from tilted or elevated remnants, but confirmation demands careful differentiation from depositional plains. Dissected variants, where fluvial activity has fragmented the original surface, further complicate recognition, as residual pediments may mimic younger features. Effective identification thus necessitates a multidisciplinary integration of geomorphological surveys to map surface geometry, stratigraphic coring to reveal underlying weathering profiles, and remote sensing—such as LiDAR or satellite imagery—to detect subtle topographic signatures and extend analysis over large areas. This holistic approach ensures robust verification while accounting for post-pediplanation modifications. Modern geomorphology continues to debate the very existence of pediplains as distinct landforms, with some researchers questioning whether observed low-relief surfaces truly represent coalesced pediments from parallel scarp retreat or are better explained by other processes like etchplanation or humid erosion. This skepticism underscores the need for rigorous criteria to avoid misidentification.

Cryoplanation Variant

Cryoplanation represents a periglacial of the pediplanation , where cold-climate mechanisms produce pediplain-like terraces and surfaces in nonglacial environments. This variant involves the formation of stepped plains through parallel retreat of scarps driven by frost action, resulting in low-relief uplands characterized by alternating treads and risers. Unlike the fluvial-dominated in warmer pediplanation, cryoplanation relies on mechanical weathering and in or seasonally frozen settings. The primary processes include cyclic freezing and thawing, which facilitate frost wedging to disintegrate along scarps, nivation to intensify beneath persistent snowpatches, and solifluction to debris downslope. These actions erode slopes at rates of approximately 0.11–0.56 cm per year, forming cryopediments—gently inclined (1–3°) surfaces veneered with 0.5–2 m of —that extend from uplands into valleys. As adjacent cryopediments coalesce through continued backwasting, they develop into broader cryoplains, extensive low-angle surfaces (<6°) often covered in unsorted . These landforms are prevalent in regions and high-altitude zones where mean annual temperatures remain below 0°C, enabling persistent frost processes. Distinct from standard pediplains, cryoplanation surfaces exhibit greater dissection by gelifluction lobes and solifluction sheets, which create lobate patterns and water tracks that channel movement. Preservation occurs under continuous , stabilizing features against post-periglacial degradation, as seen in inactive forms relict from Pleistocene conditions. Prominent examples include the plateaus of , such as the Yukon-Tanana Upland and , where cryoplains form staircase-like sequences ascending hillslopes, and Siberian uplands in the and , featuring vast cryopediment systems amid landscapes.

References

  1. [1]
    King of the plains: Lester King's contributions to geomorphology
    He considered pediplanation (scarp retreat and pedimentation) to be active in all regions where running water is responsible for shaping the land surface.Missing: pediplain | Show results with:pediplain
  2. [2]
    [PDF] Southern African Geomorphology: Recent Trends and New Directions
    Surface pediplain. This incision initiated a new cycle of landscape ... his book on South African Scenery (King, 1942), and subsequent works (King ...
  3. [3]
    [PDF] Geology of Glacier National Park and the Flathead Region ...
    L. C. King (1953). This is not the place to discuss his paper in detail, but it may be remarked that his proposal to substitute "pediplain" for "'pene-.<|control11|><|separator|>
  4. [4]
    Terminology of Surface Forms of the Erosion Cycle - jstor
    TERMINOLOGY OF SURFACE FORMS OF THE. EROSION CYCLE. JOHN H. MAXSON AND GEORGE H. ANDERSON. California Institute of Technology, Pasadena, California. ABSTRACT.
  5. [5]
    (PDF) Neogene cratonic erosion fluxes and landform evolution ...
    Apr 2, 2019 · Maxson, J.H., Anderson, G.H., 1935. Terminology of surface forms of the erosion cycle. J. Geol. 43, 88–96. Metelka, V., Baratoux, L., Naba ...<|control11|><|separator|>
  6. [6]
    [PDF] How do pediments form?: A numerical modeling investigation with ...
    In this paper, I focus on the formation of rock pediments (herein referred to simply as pediments) because these are the more enigmatic of the two types. For ...
  7. [7]
    [PDF] Pediments in Arid Environments - CalTech GPS
    Pediments have long been the subject of geomor- phological scrutiny. Furthermore, 'the origin of these landforms has been controversial since Gilbert (1877).
  8. [8]
    https://web.gps.caltech.edu/~mpl/Ge126_Reading_List/Ch13.pdf
  9. [9]
    [PDF] Planation surfaces as a record of mantle dynamics
    Jun 8, 2017 · This is a PDF file of an unedited manuscript that has been accepted for publication. ... Do pediplains exist? Suggested criteria and examples.
  10. [10]
    Relationships between African landforms, regolith materials, and ...
    Dry pedimentation periods enabled mechanical erosion and export of solid (clastic) sediments to the river system, while weathering periods mitigated solid ...
  11. [11]
    Arid and Semi-arid Region Landforms - Geology (U.S. National Park ...
    Sep 13, 2019 · Pediments are gently sloping near-bedrock surfaces at the base of a receding mountain front, formed when erosion removes much of the mountain's ...
  12. [12]
    (PDF) Landscapes and Landforms of South Africa—An Overview
    Jul 15, 2020 · ... King model whereby valleys widen over time as a result of parallel ... South African scenery. Oliver and Boyd, Edinburgh. King LC (1944) ...
  13. [13]
    https://www.researchgate.net/publication/301978232_Landscapes_and_Landforms_of_South_Africa-An_Overview
  14. [14]
    By Lester King, D.Sc., F.G.S. - Sabinet African Journals
    KING, L. C. South African Scenery. 2nd edition. Oliver & Boyd. KING, L. C. The Ages of African Land-Surfaces. Quarterly Journal of the ...
  15. [15]
    Penck's “Morphological Analysis” - Nature
    Morphological Analysis of Land Forms. A Contribution to Physical Geology. By Prof. Dr. Walther Penck. Translated By Dr. Hella Czech and Katharine Cumming ...
  16. [16]
    [PDF] Fundamentals of Geomorphology
    Fundamentals of Geomorphology begins with a consideration of the nature of geomorphology and the geomorphic system, geomorphic materials and processes, and the ...
  17. [17]
    https://geomorphology.voices.wooster.edu/wp-content/uploads/sites/135/2018/08/Fundamentals_of_Geomorphology.pdf
  18. [18]
    CANONS OF LANDSCAPE EVOLUTION | GSA Bulletin
    Mar 2, 2017 · CANONS OF LANDSCAPE EVOLUTION Available. LESTER C KING. LESTER C KING. UNIVERSITY OF NATAL, DURBAN, SOUTH AFRICA. Search for other works by ...
  19. [19]
    https://pubs.geoscienceworld.org/gsa/gsabulletin/article/64/7/721/4571/CANONS-OF-LANDSCAPE-EVOLUTION
  20. [20]
    PENEPLAINS AND PEDIPLAINS1 | GSA Bulletin - GeoScienceWorld
    Mar 2, 2017 · He is critical of a number of the assertions included by King in the “canons” of landscape evolution, advances substantial arguments against ...<|control11|><|separator|>
  21. [21]
    https://pubs.geoscienceworld.org/gsa/gsabulletin/article/68/7/913/4930/PENEPLAINS-AND-PEDIPLAINS1
  22. [22]
    [PDF] REVIEWS Comment on planation surface - SciEngine
    Abstract Planation surfaces includes peneplain, pediment and etchplain, which differ from each other in formation and distribution.
  23. [23]
    [PDF] Geography - TIMES Erosional Surfaces - AspireIAS
    This process is called etch planation. • It creates an etched plain or etchplain. The term 'etchplain' or 'etched peneplain' was originally coined to ...
  24. [24]
    [PDF] Planation surfaces as a record of mantle dynamics
    Jun 8, 2017 · (i) The African relief results from two major types of planation surfaces, etchplains. (weathering surfaces by laterites) and pediplains/ ...
  25. [25]
    Climate control on Early Cenozoic denudation of the Namibian ...
    Dec 1, 2019 · The topography of the margin is characterized by an escarpment, located 200 km away from the coast, separating low elevation pediplain from a ...
  26. [26]
    [PDF] Cenozoic deformation of the South African plateau, Namibia
    period during which the escarpment was retreating: it occurred between the formation of. 482 surface S3 (middle Eocene) and surface S6 (early Miocene). The ...
  27. [27]
    (PDF) Denudational and thermal history of the Early Cretaceous ...
    Aug 6, 2025 · The Early Cretaceous Brandberg and Okenyenya igneous complexes provide ideal locations to quantify the postbreakup denudation history of the ...
  28. [28]
    Brandberg Massif, Namibia - NASA Earth Observatory
    Jan 31, 2004 · Today the mountain of rock called the Brandberg Massif towers over the arid desert below. A ring of dark, steep-sided rocks forced upward during ...Missing: pediplains escarpment Miocene- Pliocene inselbergs
  29. [29]
    Indigenous soil knowledge among the Fulani of northern Burkina Faso
    The soil pattern in the Pétakolè territory is simple. It is dominated by slightly acid loamy/clayey pediplain soils, mainly Haplustalfs, but soil textures.
  30. [30]
    Satellite Remote Sensing of Land-use in Northern Burkina Faso
    The Oudalan province constitutes the northernmost part of Burkina Faso and belongs to the Sahelian zone (here used to describe the zone between the 200 and 600 ...
  31. [31]
    Map of Burkina Faso | Download Scientific Diagram - ResearchGate
    ... Oudalan, the northern- most province of Burkina Faso (see fig. 1). The landscape in the region is dominated by vast, ancient pediplains cut by temporal ...<|separator|>
  32. [32]
    Geomorphic evolution of southern Africa since the Mesozoic
    Jan 29, 2021 · By the end of this period a gentle pediplain. (the African surface) extended across most of southern Africa at elevations of 500-600 m. Most ...Missing: pediplains | Show results with:pediplains
  33. [33]
    5 Karoo pediplain on the high plateau, with a dolerite-capped ...
    It has an exceptionally long geologic and climatic history [2] with its Barberton Greenstone Belt in the Makhonjwa Mountains of north-eastern South Africa ...
  34. [34]
    Cenozoic stratigraphy of South Africa: current challenges and future ...
    Dec 1, 2021 · The Cenozoic stratigraphy of South Africa has developed over the past 166 years since geological mapping of the region was initiated.Missing: pediplains | Show results with:pediplains
  35. [35]
    https://pubs.geoscienceworld.org/gssa/sajg/article/124/4/817/607912/Cenozoic-stratigraphy-of-South-Africa-current
  36. [36]
    Pediment: pediplain
    When pediments coalesce in a large area, they form a pediplain. Two leading Australian ex- amples are the Barrier and Cobar pediplains; in the earlier ...
  37. [37]
    20 Pediplain in Tiruchirappalli district, Tamil Nadu. It is a landform...
    20 Pediplain in Tiruchirappalli district, Tamil Nadu. It is a landform due to denudational process. Here the soil cover is present and soil thickness may vary ...
  38. [38]
    https://www.researchgate.net/figure/Pediplain-in-Tiruchirappalli-district-Tamil-Nadu-It-is-a-landform-due-to-denudational_fig5_331859609
  39. [39]
    (PDF) Pace of Landscape Change and Pediment Development in ...
    Aug 7, 2025 · Relief reduction across the pediment begins with pediment channel incision via headward erosion. Next, tributary drainage capture begins and ...
  40. [40]
    The Geologic Origin of the Sonoran Desert
    The Sonoran Desert lies in a region of the West called the Basin and Range geologic province. This curious country consists of broad, low-elevation valleys.Missing: pediplain | Show results with:pediplain
  41. [41]
    Dating by cosmogenic nuclides | U.S. Geological Survey - USGS.gov
    These nuclides, including 3 He, 10 Be, 14 C, 21 Ne, 26 Al, and 36 Cl, enable dating of landforms and the measurement of erosion rates.Missing: pediplain | Show results with:pediplain
  42. [42]
    https://www.usgs.gov/publications/dating-cosmogenic-nuclides
  43. [43]
    https://doi.org/10.1016/B978-0-323-99931-1.00111-2