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A yardang near Meadow, Texas (33°19′16″N 102°29′42″W / 33.321°N 102.495°W / 33.321; -102.495) (USDA photo).
Yardangs in the Qaidam Desert, Qinghai Province, China.

A yardang is a streamlined protuberance carved from bedrock or any consolidated or semiconsolidated material by the dual action of wind abrasion by dust and sand and deflation (the removal of loose material by wind turbulence).[1] Yardangs become elongated features typically three or more times longer than wide, and when viewed from above, resemble the hull of a boat. Facing the wind is a steep, blunt face that gradually gets lower and narrower toward the lee end.[2] Yardangs are formed by wind erosion, typically of an originally flat surface formed from areas of harder and softer material. The soft material is eroded and removed by the wind, and the harder material remains. The resulting pattern of yardangs is therefore a combination of the original rock distribution, and the fluid mechanics of the air flow and resulting pattern of erosion.

Names

[edit]

The word itself is of Turkic origin,[3][4] meaning 'steep bank', as this type of spectacular landscapes rising 25–50 feet (8–15 m) are best developed in the interior deserts of this region.[5] And the word was first introduced to the English-speaking world by the Swedish explorer Sven Hedin in 1903.[6] In China, they are sometimes known as yadan from the Chinese adaptation of the Uyghur form of the same name.[7]

Other names for them are "mud-lions",[8][9] "mushroom rocks", "sphinx-like hills", "koukour" in Tunisia, and "kalut" (Persian for "ridge") in Iran.[10] The massive features of mega-yardangs are called "ridges and corridors" (crêtes et couloirs) in French.[11]

Yardangs on water in the Usut Yardang Geological Park, Qinghai, China

Description

[edit]

A yardang is formed in cohesive material.[12] Hedin first[citation needed] found the wind-sculptured "clay terraces" or yardangs in the dried up riverbed of the Kurruk-daria in Central Asia. However, yardangs can be found in most deserts across the globe.[13] Depending upon the winds and the composition of the weakly indurated deposits of silt and sand from which they are carved, yardangs may form very unusual shapes — some resemble various objects, people or even lying lions.[14]

Yardangs come in a large range of sizes, and are divided into three different categories: mega-yardangs, meso-yardangs, and micro-yardangs. Mega-yardangs can be several kilometers long and hundreds of meters high and are found in arid regions with strong winds; meso-yardangs are generally a few meters high and 10 to 15 meters long and are commonly found carved in semiconsolidated playa sediments and other soft granular materials; and micro-yardangs are only a few centimeters high.

A large concentration of mega-yardangs occurs near the Tibesti Mountains in the central Sahara. There is a famous yardang at Hole in the Rock in Papago Park in Phoenix, Arizona, a rock formation with a roughly circular hole in it. Another yardang in Arizona is Window Rock, near the town of Window Rock. It is a 60-meter sandstone hill with a very large circular hole in the middle of it. Some geologists have suggested that the Great Sphinx of Egypt is an augmented yardang.[15]

Yardangs in Lucus Planum (Mars)

Pictures from Mars show that the yardang ridges occur on a massive scale there; some individual ridges are tens of kilometers long with intervening valleys nearly 1 km wide. Yardangs on Mars are typically found in the Amazonis region but the best ones are found in the equatorial region. Yardangs on Mars demonstrate that much of the eolian erosion is recent since they are sculpted in young geologic units.[16]

Formation

[edit]

Explaining the formation of yardangs is challenging. It occurs due to the coupled evolution of complex flow fields and three-dimensional (3D) topographies in the context of harder or less erodible material embedded in softer material. The carving of the geometrical features is generated by differential erosion caused by flow strength, flow funneling, and turbulent wakes.[14]

Yardangs are formed in environments where water is scarce and the prevailing winds are strong, uni-directional, and carry an abrasive sediment load. The wind cuts down low-lying areas into parallel ridges which gradually erode into separate hills that take on the unique shape of a yardang. This process yields a field of yardangs of roughly the same size, commonly referred to as a fleet due to their resemblance to the bottoms of ships. Alternatively, one can be formed by the migration of a dune that leaves behind a cemented core. As the process of formation continues, typically a trough will form around the base of the yardang. Most yardang fields are in sand-poor areas, but the associated troughs, especially in grooved terrain, may be invaded by sand. Sometimes this sand will accumulate to build shallow moats around the bottom.

They are more commonly created from softer rock types like siltstone, sandstone, tuff or Ignimbrite, shale, and limestone, but have also been observed in crystalline rocks such as schist and gneiss.

See also

[edit]
  • Aeolian processes – Processes due to wind activity
  • Barchan – Crescent-shaped dune
  • Blowout – Depressions in a sand dune ecosystem caused by the removal of sediments by wind
  • Dune – Hill of loose sand built by aeolian processes or the flow of water
  • Dunhuang Yardang National Geopark – Protected area in Gansu Province, China, China
  • Hoodoo (geology) – Tall, thin spire of relatively soft rock usually topped by harder rock
  • Lop Desert – Desert in China
  • Mushroom rock – Mushroom-shaped rock formation
  • Saltation – Particle transport by fluids
  • Sandhill – Type of ecological community or xeric wildfire-maintained ecosystem
  • Ventifact – Rock that has been eroded by wind-driven sand or ice crystals

References

[edit]
[edit]
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Yardang

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from Grokipedia
A yardang is a streamlined, elongated sculpted primarily by in arid environments, consisting of ridges or hills with sharp crests and fluted surfaces, often oriented parallel to prevailing directions. These features form through aeolian abrasion and , where carrying abrasive particles erodes softer sedimentary rocks, such as those from , , or Tertiary periods, while harder layers resist to create asymmetric shapes with steep windward faces and gentler leeward slopes. Yardangs vary in scale from small ridges a few meters long to massive structures spanning kilometers, with aspect ratios (length-to-width) typically ranging from 1:1 to over 5:1, influenced by structure, compressive strength, and patterns. Yardangs are prevalent in hyper-arid desert regions worldwide, including the on the in , the Ocotillo Wells area in , and the and Basins in , , where they cover extensive areas up to 6,000 km² and exhibit diverse morphologies such as castle-like towers, isolated hills, and bluff formations in colors ranging from light brown to red and green. Formation processes involve mechanisms, where concentrates in inter-yardang troughs, accelerating flux and further sculpting, with rates estimated at 3–4 mm per year in active settings. Beyond Earth, similar yardangs occur on Mars and , serving as analogs for understanding extraterrestrial , particularly wind-driven processes in low-gravity or thin-atmosphere environments. The Yardangs, recognized for their concentration, preservation, and representation of arid temperate zone evolution, highlight the role of these landforms in recording paleoclimatic changes and tectonic uplift, such as that of the Qinghai-Tibet Plateau.

Etymology and Terminology

Origin of the Name

The term "yardang" derives from Turkic languages, particularly the Uighur word "yar," meaning "steep bank" or "ravine," and was adapted to denote wind-eroded ridges in desert environments. This linguistic root reflects the features' characteristic steep, sculpted profiles, which resemble eroded banks along river courses but formed by aeolian processes. Swedish explorer first introduced the term to Western scientific literature in 1903, during his expeditions across , specifically while documenting landforms in the Tarim Basin region of . In his publication Central Asia and Tibet: Towards the Holy City of Lassa in the Heart of Asia, Hedin described these formations encountered in arid, wind-swept terrains, marking the initial Western recognition of yardangs as distinct geomorphic entities. His observations, drawn from fieldwork in the area, provided the earliest detailed accounts, emphasizing their streamlined shapes resulting from persistent wind action. Following Hedin's introduction, the term "yardang" rapidly entered English-language geological discourse, appearing in subsequent studies of arid landforms by the early . Early adoptions occasionally included variations, such as "jardang," reflecting inconsistencies in rendering the Turkic into . In , where many prominent examples occur, the local Uighur designation evolved into the Mandarin term "yadan," used interchangeably for these features in regional contexts.

Regional Variations

In various regions, yardangs are known by local terms that reflect cultural interpretations of their shapes and prominence in the landscape. In , particularly within the , the term "yadan" is widely used, derived from the where it signifies a small hill with steep escarpments or steep rocks, emphasizing the abrupt, cliff-like edges of these formations. This name gained popularity through descriptions of expansive yadan landscapes in areas like , where the features are celebrated for their dramatic, otherworldly appearance. In , the equivalent term is "kalut," a Persian word meaning "ridge," applied to yardang-like structures in the that often evoke isolated, castle-like silhouettes due to their towering, fortified profiles. These formations are noted for their resemblance to ancient bastions, aligning with local perceptions of the desert's rugged, defensive terrain. Further synonyms appear in North African contexts, such as "koukour" in , highlighting similar wind-sculpted hills in arid environments. In informal English geological descriptions, yardangs are sometimes called "mud-lions" or "sphinx-like hills," drawing on their animalistic contours that mimic recumbent beasts or mythical figures, a tracing back to early 20th-century explorers like . French literature refers to mega-yardang assemblages as "ridges and corridors" (crêtes et couloirs), underscoring the linear, channeled patterns observed in Saharan settings. These varied names illustrate how regional cultures anthropomorphize or structurally interpret the landforms as guardians, creatures, or architectural remnants.

Description and Morphology

Physical Features

Yardangs are elongated, streamlined ridges that are often more than three times longer than they are wide, exhibiting a characteristic asymmetry with a blunt, steep upwind face and a tapered, sloping downwind end that resembles the hull of a or the of an . This streamlined form arises from the prevailing wind direction, which sculpts the upwind end into a near-vertical while eroding the downwind side into a gentler taper. The surfaces of yardangs often display distinctive textures resulting from wind abrasion, including longitudinal flutes, parallel grooves, and polished facets known as ventifacts, particularly on exposed windward faces. These features are commonly developed on materials such as cohesive sediments like and claystone, or softer sedimentary rocks including and , which provide sufficient induration to resist complete while allowing sculpted forms to emerge. Internally, yardangs are frequently composed of layered sedimentary rocks where variations in —such as alternating resistant beds and more friable layers—promote the preservation of the ridge by protecting underlying material from uniform . Typical dimensions for meso-scale yardangs include heights ranging from a few meters to tens of meters and lengths extending up to a few hundred meters, contributing to their prominent relief in arid landscapes.

Classification by Size

Yardangs are categorized by size into three principal classes—micro-yardangs, meso-yardangs, and mega-yardangs—primarily based on their , , and length-to-width ratios often exceeding 3:1, which indicates aerodynamic streamlining. This ratio, often approaching an ideal 4:1 for mature forms, reflects equilibrium with prevailing wind regimes across all size classes. The classification emphasizes dimensional hierarchies, with larger forms exerting greater influence on surrounding due to their scale. Micro-yardangs represent the smallest scale, typically ranging from centimeters to about 1 meter in height and length, and are observable in hand samples or through laboratory as delicate erosional features. These diminutive structures allow detailed study of initial patterns at fine resolutions. Meso-yardangs, the most extensively researched category, measure 1 to 100 meters in height and several meters to a few hundred meters in length, commonly forming extensive fields of parallel that facilitate investigations into mid-scale aeolian dynamics. Their dimensions enable field-based morphometric , highlighting variations in alignment and spacing. Mega-yardangs achieve kilometer-scale lengths, often 1 to 10 kilometers long with heights exceeding 100 meters, dominating landscapes in expansive basins and altering regional drainage and patterns. Their vast extent requires for comprehensive mapping, underscoring their role in shaping broad geomorphic provinces.

Formation and Processes

Erosional Mechanisms

The primary erosional mechanism shaping yardangs is wind abrasion, also known as corrasion, where saltating sand grains carried by impact and erode exposed rock surfaces, particularly on the upwind faces of nascent ridges. These grains, typically 80–120 μm in diameter and moving at heights of 0.1–1 m above the surface, deliver kinetic energy that concentrates in areas of high , such as troughs between proto-yardangs, with fluxes following a power-law distribution (q_s ∝ z^{-2.5}) indicative of saltation-suspension dynamics. This process is most effective in environments with persistent unidirectional winds, resulting in streamlined forms that minimize aerodynamic drag. Complementing abrasion, deflation removes loose, fine-grained particles directly by wind lift through turbulent eddies, isolating ridges by selectively eroding softer inter-ridge material and enhancing overall landscape dissection. This mechanism operates without requiring impacting grains, though it often synergizes with abrasion to lower relief in unconsolidated substrates, contributing to rates of several millimeters per year in active fields. is particularly pronounced in troughs where wind speeds increase due to topographic channeling, further refining yardang boundaries. Differential plays a crucial role, where variations in rock resistance—such as harder caps or layers of (compressive strength 5–50 MPa) overlying weaker strata—protect underlying material from abrasion and , leading to inverted as surrounding softer plains are preferentially removed. This creates emergent ridges from initially flat or low- surfaces, with erodibility contrasts (e.g., 100:1) accelerating undercutting and exposing resistant inclusions as prominent "heads." In heterogeneous substrates, such as layered sediments, this process yields complex morphologies, including fluted surfaces and ledges. These mechanisms are amplified by loops, wherein initial small obstacles generate wind shadows on leeward sides, reducing there while accelerating it in adjacent softer areas through flow funneling and turbulent wakes. As troughs deepen, they accommodate higher fluxes, further isolating and elongating ridges in a self-reinforcing cycle that evolves yardangs toward aspect ratios of approximately 4:1. This autogenic dynamic ensures progressive refinement until structural limits or external factors intervene.

Required Environmental Conditions

Yardangs develop exclusively in arid to semi-arid climates where annual is minimal, typically less than 100 mm per year, to suppress water-driven and favor that sculpt features. Such low rainfall limits vegetation growth and , maintaining bare surfaces vulnerable to action while preventing dilution of the abrasive load. Fluctuating dry-wet cycles may contribute by periodically exposing and drying sediments, but sustained is crucial for long-term preservation of yardang morphology. Strong, unidirectional are a fundamental prerequisite, with sustained speeds often exceeding 20 km/h to effectively transport and impact particles like and against the substrate. These winds must be consistent in direction to align yardang orientations and elongate forms parallel to , with episodic high-velocity events (e.g., over 15 m/s for brief periods) enhancing erosion efficiency. Abrasion by this wind-borne load serves as the primary erosive mechanism under these conditions. The underlying must be erodible yet cohesive, such as friable lacustrine or fluvial deposits including claystones, siltstones, and mudstones with compressive strengths around 5–50 MPa, allowing selective sculpting without total removal. These materials, often porous and fine-grained, form in flat to gently sloping terrains that permit unobstructed flow and minimize topographic interference. A steady supply from nearby sources, such as desiccated lake beds or sheets, is essential to sustain abrasion, providing grains typically 80–120 μm in while avoiding depositional dominance that could smother developing yardangs. This supply ensures continuous transport of abrasive material into erosional zones without overwhelming the system.

Global Distribution

Major Regions

Yardangs are primarily distributed in wind-dominated arid environments across the globe, where persistent aeolian erosion shapes soft sedimentary rocks into streamlined forms. In , extensive yardang fields dominate hyper-arid landscapes, with hosting the largest concentration covering approximately 20,000 km², particularly in the Gobi and Taklamakan Deserts as well as the on the . The Lut Desert in features prominent mega-yardangs, up to several kilometers long, sculpted from Pleistocene alluvial deposits. Africa's Desert contains vast yardang complexes, with notable concentrations in the central and , where mega-yardangs reach heights exceeding 100 meters. In Tunisian regions of the northern , yardangs form in erodible sediments along systems, contributing to the desert's deflationary surfaces. In , yardangs are concentrated in the of the , exemplified by fields at Rogers Lake in , where wind erosion has streamlined lacustrine clays into teardrop-shaped forms. Further south in the , particularly Arizona badlands and desert margins, smaller yardang clusters develop in unconsolidated alluvial and lacustrine deposits. Elsewhere, yardangs occur scattered in the hyper-arid of , where they emerge from wind-eroded volcanic and alluvial materials. In Australia's , isolated yardang features appear in arid interior basins, though less extensive than in Asian counterparts. Overall, yardangs prevail in hyper-arid zones, which encompass about 4.2% of Earth's land surface within broader covering roughly 30%.

Notable Examples

One prominent example of yardangs is found in the Yardang National Geopark in China's Province, a Global spanning approximately 398 square kilometers in the . These formations consist of dense, wind-eroded rock structures, including ridge-shaped yardangs resembling a fleet of ships, developed in Tertiary sediments under extreme aridity. The site features castle-like mega-yardangs reaching heights of up to 40 meters, highlighting long-term aeolian erosion processes in a temperate desert environment. It was nominated as a tentative due to its exceptional geoheritage value. In Iran's Lut Desert, a , the kaluts—local term for yardangs—represent some of the most dramatic and well-preserved examples globally, formed in lacustrine silt, clay, and silty clay strata through hydro-aeolian processes. These isolated, sculptural forms, often evoking ancient ruins, can tower up to 150 meters tall and cover vast unbroken expanses, showcasing the desert's extreme aridity, including record surface temperatures exceeding 70°C. The yardang/kalut landforms here are renowned for their scale, continuity, and height, making the Lut one of the premier sites for studying intense wind erosion in hyper-arid conditions. Closer to urban areas, the Hole-in-the-Rock formation in Phoenix's , , exemplifies meso-scale yardangs developed in soft volcanic and conglomerate deposits approximately 20 million years old. This roadside accessible site, reachable via a short , features eroded red rock buttes with cavities formed by wind and water, illustrating how erosional processes operate near modern development. Its proximity to the city underscores the transition from arid natural landscapes to human-influenced environments. Similarly, Window Rock in Arizona's serves as a cultural and geological landmark, where yardang-like erosional arches have been sculpted from Entrada through prevailing arid wind erosion. The prominent 60-meter-high arch, with its distinctive circular opening, blends natural wind-carved morphology with deep cultural significance for the people, who named their capital after this feature. This site demonstrates how yardang processes can produce iconic, arch-shaped landforms in semi-arid settings.

Significance and Research

Geological Indicators

Yardangs serve as valuable paleowind direction indicators due to the linear alignment of their ridges, which typically orient parallel to prevailing historical wind patterns, allowing geologists to reconstruct ancient on . This alignment arises from the erosional sculpting process, where wind consistently abrades the upwind faces while protecting the leeward sides, resulting in streamlined forms that preserve directional evidence over geological timescales. For instance, in arid regions like the , yardang orientations have been analyzed to model both modern and paleo wind regimes, contributing to broader understandings of global climate dynamics. The presence of yardangs in hyper-arid basins acts as a climate proxy, signaling prolonged periods of extreme dryness essential for their formation and persistence, as these landforms require sustained and minimal to avoid fluvial disruption. Dating techniques, such as analysis (e.g., 10Be), have been applied to yardang surfaces and capping sediments to estimate formation timelines, revealing ages ranging from thousands to millions of years that align with major shifts to hyperarid conditions. In the , for example, cosmogenic exposure dating of yardang-capped fluvial terraces indicates initial formation around 105 ka during the , a time of intensified , with ongoing evolution through the . Erosion rate studies of yardangs employ numerical models to quantify wind strength and sediment flux, providing insights into the rates and drivers of landscape evolution in desert environments. These models simulate positive feedbacks between topography, near-surface wind speeds (with effective shear velocities of 0.4–0.8 m/s), and eolian sediment transport, where flux peaks in inter-yardang troughs following power-law distributions. Such analyses yield long-term erosion rates of 0.25 mm/year in the Qaidam Basin over the past 105 ka, with higher rates (0.26 mm/year) during glacial aridity compared to interglacial periods (0.15 mm/year), helping to track desertification trends and predict future aridification under changing climates. A 2025 study on yardangs downstream of the Peacock River in NW China reports historical erosion rates of 0–1.54 cm/year (since ~565 years BP) and current short-term rates of 0–3.0 cm/year using 3D laser scanning, indicating lower recent rates in some areas compared to historical values. In regions like California's Ocotillo Wells, short-term terrestrial laser scanning data confirm rates of 3–7 mm/year, underscoring the role of wind as the dominant erosional agent. Recent research, including a 2025 large-scale mapping of over 680,000 yardangs in the Qaidam Basin, quantifies environmental controls, showing rainfall hinders development (34% effect) while substrate, wind, and topography promote it (31%, 20%, 15% effects). A 2024 study further demonstrates that erosion of heterogeneous materials produces complex yardang morphologies through shape-flow feedback. Certain yardangs near human settlements have been hypothesized to influence ancient cultural landscapes, such as those in the , where natural wind-eroded formations may have inspired or served as precursors to monuments like the Great Sphinx. Laboratory experiments replicating yardang development in soft limestone-like materials under wind-mimicking flows have produced Sphinx-resembling shapes, including an undercut neck and protruding "paws," supporting the idea that enhanced pre-existing yardangs around 4,500 years ago. However, this remains debated, as direct geological linking specific yardangs to the Sphinx is limited, and traditional views emphasize primarily anthropogenic carving.

Extraterrestrial Yardangs

Yardangs are prevalent on Mars, particularly in regions such as Amazonis Planitia and the Medusae Fossae Formation, where they form extensive fields of streamlined erosional landforms sculpted by wind. A 2024 study identifies over 41,000 scour pits in the Medusae Fossae Formation as proto-yardangs, suggesting a developmental link to mature yardangs and expanding the formation's extent by approximately 15%. These features were first identified through Viking Orbiter imagery in the late and have been extensively documented by subsequent missions, including high-resolution images from the Mars Orbiter's camera, revealing yardang heights up to 200 meters and aspect ratios ranging from 3:1 to 50:1. On Mars, with its thin atmosphere approximately 1% as dense as Earth's, these yardangs indicate ongoing and past eolian activity, where winds transport sediments and erode softer materials into isolated ridges aligned with prevailing wind directions. Potential yardang-like formations have been hypothesized on other celestial bodies with atmospheres, though less definitively than on Mars. On Titan, Saturn's largest moon, candidate yardangs up to 9 kilometers long with length-to-width ratios around 20:1 have been identified in mid-latitude blandlands, potentially shaped by methane-driven erosion in a nitrogen-methane atmosphere. Similarly, on , wind-eroded features resembling yardangs surround Mead crater, with recent morphometric analyses supporting aeolian origins influenced by the planet's dense, super-rotating atmosphere. In contrast, airless bodies like the lack such formations due to the absence of an atmosphere capable of sustaining wind-driven erosion, relying instead on impact and thermal processes for surface modification. Extraterrestrial yardangs serve as key analogs for understanding planetary wind regimes and sediment transport, informing Mars rover missions such as Perseverance in Jezero Crater, where aeolian features like ventifacts help reconstruct past atmospheric conditions. These landforms provide insights into how thinner atmospheres facilitate eolian processes, with applications to modeling dust mobilization and climate evolution on Mars. Seminal research includes Ward's 1979 analysis, which established yardangs as evidence of recent Martian wind erosion, while 2024 observations from the Curiosity rover's imaging of the Yardang Unit in Gale Crater link these features to ancient climatic shifts.

References

  1. https://whc.unesco.org/en/tentativelists/5989/
  2. https://geomorphology.geo.arizona.edu/PAPERS/pelletier_etal_18a.pdf
  3. https://doi.org/10.1002/2017JF004461
  4. https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2018je005719
  5. https://compass.onlinelibrary.wiley.com/doi/10.1111/j.1749-8198.2006.00003.x
  6. https://www.sciencedirect.com/science/article/abs/pii/S0034425708001430
  7. https://books.google.com/books/about/Central_Asia_and_Tibet.html?id=B0xwAAAAMAAJ
  8. https://www.mdpi.com/2072-4292/14/21/5628
  9. https://www.taylorfrancis.com/chapters/edit/10.4324/9780429299230-12/yardangs-john-mccauley-maurice-grolier-carol-breed
  10. https://www.collinsdictionary.com/us/dictionary/english/yardang
  11. http://www.dhdzgy.com/en/keyan/1269.html
  12. https://whc.unesco.org/en/tentativelists/5990/
  13. https://en.people.cn/n3/2021/0712/c90000-9870941.html
  14. https://www.chinadaily.com.cn/a/202504/05/WS67f08649a3104d9fd381db20.html
  15. https://newspaper.irandaily.ir/7297/4/2035
  16. https://whc.unesco.org/en/list/1505/
  17. https://iugs-geoheritage.org/geoheritage_sites/yardang-kalut-in-the-lut-desert/
  18. https://apps.dtic.mil/sti/tr/pdf/ADA244855.pdf
  19. https://eos.org/articles/did-these-curious-rock-formations-inspire-the-great-sphinx
  20. https://www.bu.edu/bridge/archive/2001/04-20/elbaz.html
  21. https://www.sciencedirect.com/science/article/abs/pii/S0169555X01000265
  22. https://agupubs.onlinelibrary.wiley.com/doi/full/10.1002/2017JF004461
  23. https://www.sciencedirect.com/science/article/abs/pii/S1875963723000149
  24. https://digitalcollections.wesleyan.edu/_flysystem/fedora/2024-08/2062.pdf
  25. https://www.pnas.org/doi/10.1073/pnas.2322411121
  26. https://pubs.usgs.gov/publication/70012664
  27. https://link.springer.com/chapter/10.1007/978-1-4020-5719-9_19
  28. https://link.springer.com/article/10.1007/s00531-024-02409-7
  29. https://www.sciencedirect.com/science/article/abs/pii/S0169555X20302026
  30. https://ui.adsabs.harvard.edu/abs/2016AeoRe..20...89L/abstract
  31. https://jdesert.ut.ac.ir/article_35262_0.html/article_62251.html
  32. https://digitalcommons.unl.edu/cgi/viewcontent.cgi?article=1180&context=usgspubs
  33. https://www.researchgate.net/publication/324169169_Controls_on_Yardang_Development_and_Morphology_1_Field_Observations_and_Measurements_at_Ocotillo_Wells_California
  34. https://www.researchgate.net/publication/227681788_Mega-Yardangs_A_Global_Analysis
  35. https://www.fao.org/4/t0122e/t0122e03.htm
  36. https://www.unesco.org/en/iggp/dunhuang-unesco-global-geopark
  37. https://aroundus.com/p/6476834-dunhuang-yardang-national-geopark
  38. https://worldheritagesite.org/tentative/dunhuang-yardangs/
  39. https://www.azcentral.com/story/news/local/phoenix-contributor/2016/04/19/hole-rock-papago-park/83217684/
  40. https://www.atlasobscura.com/places/hole-in-the-rock-phoenix
  41. https://www.worldatlas.com/articles/aeolian-landforms-what-is-a-yardang.html
  42. https://scholarsarchive.byu.edu/etd/6781/
  43. https://www.nps.gov/subjects/geology/aeolian-landforms.htm
  44. https://www.researchgate.net/publication/320411660_Yardang_Geometries_in_the_Qaidam_Basin_and_Their_Controlling_Factors
  45. https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2019GL082992
  46. https://agupubs.onlinelibrary.wiley.com/doi/full/10.1002/2018JF004629
  47. https://doi.org/10.1007/s43217-025-00253-6
  48. https://doi.org/10.1016/j.geomorph.2024.109575
  49. https://www.nyu.edu/about/news-publications/news/2023/october/did-nature-have-a-hand-in-the-formation-of-the-great-sphinx--.html
  50. https://journals.aps.org/prfluids/abstract/10.1103/PhysRevFluids.8.110503
  51. https://www.scientificamerican.com/article/egypts-iconic-sphinx-may-have-begun-as-natural-carving-by-the-wind/
  52. https://www.nature.com/articles/s41467-018-05291-5
  53. https://doi.org/10.1029/2024JE008664
  54. https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2001JE001537
  55. https://agupubs.onlinelibrary.wiley.com/doi/abs/10.1029/JB084iB14p08147
  56. https://www.hou.usra.edu/meetings/lpsc2015/pdf/2746.pdf
  57. https://www.lpi.usra.edu/publications/slidesets/winds/
  58. https://agupubs.onlinelibrary.wiley.com/doi/full/10.1029/2022JE007599
  59. https://www.jpl.nasa.gov/images/pia26472-curiosity-views-the-yardang-unit/
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