Hubbry Logo
MudcrackMudcrackMain
Open search
Mudcrack
Community hub
Mudcrack
logo
8 pages, 0 posts
0 subscribers
Be the first to start a discussion here.
Be the first to start a discussion here.
Mudcrack
Mudcrack
Mudcrack
View on Wikipedia
from Wikipedia

Fresh mudcracks on the shore of The Wash, England

Mudcracks (also known as mud cracks, desiccation cracks or cracked mud) are sedimentary structures formed as muddy sediment dries and contracts.[1][2] Crack formation also occurs in clay-bearing soils as a result of a reduction in water content.

Formation of mudcrack

[edit]
Top layer shrinks and curls up due to the strain
Crack pattern in clay exposed to the air

Naturally forming mudcracks start as wet, muddy sediment dries up and contracts. A strain is developed because the top layer shrinks while the material below stays the same size. When this strain becomes large enough, channel cracks form in the dried-up surface to relieve the strain. Individual cracks spread and join up, forming a polygonal, interconnected network of forms called "tesselations." If the strain continues to build, the polygons start to curl upwards. This characteristic can be used in geology to understand the original orientation of a rock.[3] Cracks may later be filled with sediment and form casts over the base.[citation needed]

Typically, the initial crack pattern is dominated by T-shaped junctions. If a mudfield is repeatedly wetted and dried, it can be annealed to a pattern dominated by Y-shaped junctions, as it is thermodynamically favored like columnar jointing and polygonal patterned ground.[4]

Syneresis cracks are broadly similar features that form from underwater shrinkage of muddy sediment caused by differences in salinity or chemical conditions,[1] rather than aerial exposure and desiccation. Syneresis cracks can be distinguished from mudcracks because they tend to be discontinuous, sinuous, and trilete or spindle-shaped.[5]

Morphology and classification of mudcrack

[edit]

Mudcracks are generally polygonal when seen from above and v-shaped in cross section. The "v" opens towards the top of the bed and the crack tapers downward. Allen (1982) proposed a classification scheme for mudcracks based on their completeness, orientation, shape, and type of infill.[5]

Completeness of mudcrack

[edit]

Complete mudcracks form an interconnected tessellating network. The connection of cracks often occurs when individual cracks join together forming a larger continuous crack.[5] Incomplete mudcracks are not connected to each other but still form in the same region or location as the other cracks.[5]

Plan-view geometry

[edit]

Orthogonal intersections can have a preferred orientation or may be random. In oriented orthogonal cracks, the cracks are usually complete and bond to one another forming irregular polygonal shapes and often rows of irregular polygons. In random orthogonal cracks, the cracks are incomplete and unoriented therefore they do not connect or make any general shapes. Although they do not make general shapes they are not perfectly geometric.[6] Non-orthogonal mudcracks have a geometric pattern. In uncompleted non-orthogonal cracks they form as a single three-point star shape that is composed of three cracks. They could also form with more than three cracks but three cracks in commonly considered the minimum. In completed non-orthogonal cracks, they form a very geometric pattern. The pattern resembles small polygonal shaped tiles in a repetitive pattern.[5]

Mud curls

[edit]

Mud curls form during one of the final stages in desiccation. Mud curls commonly occur on the exposed top layer of very thinly bedded mud rocks. When mud curls form, the water that is inside the sediment begins to evaporate causing the stratified layers to separate. The individual top layer is much weaker than multiple layers and is therefore able to contract and form curls as desiccation occurs.[6] If transported by later currents, mud curls may be preserved as mud-chip rip-up clasts.

Environments and substrates

[edit]

Naturally occurring mudcracks form in sediment that was once saturated with water. Abandoned river channels, floodplain muds, and dried ponds are localities that form mudcracks.[7] Mudcracks can also be indicative of a predominately sunny or shady environment of formation. Rapid drying, which occurs in sunny environments, results in widely spaced, irregular mudcracks, while closer spaced, more regular mudcracks indicate that they were formed in a shady place.[8] Similar features also occur in frozen ground, lava flows (as columnar basalt), and igneous dykes and sills.[9]

In technology

[edit]

Polygonal crack networks similar to mudcracks can form in human-made materials such as ceramic glazes, paint film, and poorly made concrete. Mudcrack patterning at smaller scales can also be observed studied using technological thin films[10][11] deposited using micro and nanotechnologies.[12]

Preservation of mudcrack

[edit]
Ancient mudcracks preserved on the base of a bed of sandstone

Mudcracks can be preserved as v-shaped cracks on the top of a bed of muddy sediment or as casts on the base of the overlying bed. When they are preserved on the top of a bed, the cracks look as they did at the time of formation. When they are preserved on the bottom of the bedrock, the cracks are filled in with younger, overlying sediment. In most bottom-of-bed examples, the cracks are the part that sticks out most. Bottom-of-bed preservation occurs when mudcracks that have already formed and are completely dried are covered with fresh, wet sediment and are buried. Through burial and pressure, the new wet sediment is further pushed into the cracks, where it dries and hardens. The mudcracked rock is then later exposed to erosion.[2] In these cases, the original mud cracks will erode faster than the newer material that fills the spaces. This type of mudcrack is used by geologists to determine the vertical orientation of rock samples that have been altered through folding or faulting.[13]

[edit]
  • Bedding plane view of ancient mudcracks
    Bedding plane view of ancient mudcracks
  • Cross-sectional view of ancient mudcrack
    Cross-sectional view of ancient mudcrack
  • Mudcracks in the Carmel Formation (Middle Jurassic) near Gunlock, Utah.
    Mudcracks in the Carmel Formation (Middle Jurassic) near Gunlock, Utah.

See also

[edit]

References

[edit]
[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Mudcrack

View on Grokipedia
from Grokipedia
Mudcracks, also known as cracks or mud cracks, are that form when fine-grained clay-rich dry out and contract, resulting in a network of interconnected polygonal fractures on the surface. These cracks typically develop in environments such as floodplains, tidal flats, or shallow lakes where muddy deposits are periodically exposed to air during low levels or dry seasons, causing the loss of moisture and subsequent shrinkage of the sediment. In geological contexts, mudcracks serve as key indicators of past environmental conditions, revealing episodes of exposure and in ancient sedimentary basins. They are preserved in the rock record when coarser sediments, such as or , fill the cracks before the surrounding can rehydrate and close them, often followed by burial under additional layers. The morphology of mudcracks varies, with crack patterns ranging from irregular to more regular hexagonal polygons depending on the composition and drying rate; slower drying tends to produce smaller, more closely spaced polygons, while rapid drying results in larger, more widely spaced polygons. Beyond their role in paleoenvironmental reconstruction, mudcracks are valuable as way-up structures in , helping geologists determine the original orientation of sedimentary layers since the cracks open upward and their infill is typically coarser material from above. Examples of preserved mudcracks are found in formations worldwide, such as the Pleistocene sediments of or ancient mudstones in various basins, providing insights into Earth's climatic and depositional history. Analogous desiccation crack patterns also occur in non-geological settings, including technological materials and extraterrestrial environments such as Mars.

Formation

Desiccation Process

Mudcracks, also known as desiccation cracks, are that form through the contraction of water-saturated, clay-rich sediments as is lost primarily via . These fine-grained materials, dominated by clay minerals, initially swell when saturated but shrink upon drying, creating tension within the deposit. This process is fundamental to the development of cracks in environments where sediments are exposed to air after deposition. The process unfolds in stages. first causes uniform volumetric shrinkage across the layer, as is removed from pore spaces and between clay particles, leading to a buildup of tensile stresses due to the material's to the underlying substrate and lateral constraints. When these tensile stresses exceed the sediment's cohesion, cracks initiate at the surface, often at points of weakness such as minor irregularities or the largest pores. The cracks then propagate downward through the layer, typically following a path to the surface, as the ongoing shrinkage continues to pull the material apart. This propagation is driven by the release of stored , allowing the surrounding sediment to relax. Capillary forces play a critical role by facilitating movement to the evaporating surface, where menisci form between particles, generating negative pore pressures that enhance and contribute to the tensile stress field. These forces also influence the of crack networks, promoting the development of interconnected polygonal patterns as cracks intersect to minimize . In clay-rich sediments, the suction draws air into pores progressively, accelerating the uneven shrinkage at the surface and favoring orthogonal or hexagonal arrangements. The underlying physics can be described using basic principles of shrinkage and elasticity. The shrinkage strain ϵ\epsilon is defined as the relative volume change due to water loss: ϵ=ΔVV\epsilon = \frac{\Delta V}{V} where ΔV\Delta V is the change in volume and VV is the initial volume of the saturated sediment. Under constrained conditions, this strain induces tensile stress σ=Eϵ\sigma = E \epsilon, with EE representing the elastic modulus of the sediment, which varies with clay content and water saturation but typically ranges from 1 to 10 MPa for cohesive soils. Cracking occurs when σ\sigma surpasses the material's tensile strength, often around 10-50 kPa. Experimental studies confirm that visible crack formation requires a minimum sediment thickness, typically 1-10 cm, to allow sufficient stress accumulation before propagation; thinner layers may desiccate without fracturing.

Influencing Factors

The development of mudcracks is profoundly influenced by sediment composition, particularly the proportion and type of clay minerals present. Sediments dominated by clays such as (including ) or display heightened shrink-swell potential owing to their layered structures, which enable significant water adsorption during wetting and substantial volumetric contraction upon . This property amplifies tensile stresses, promoting crack initiation and wider crack apertures compared to coarser or kaolinite-rich sediments. Environmental conditions exert primary control over the evaporation rate, which in turn dictates the pace and intensity of mudcrack formation. Elevated temperatures, reduced relative humidity (e.g., around 52%), and higher wind speeds enhance moisture loss, accelerating drying and thereby hastening crack propagation while favoring more extensive networks. Conversely, slower under humid or calm conditions delays cracking and may result in shallower or less interconnected patterns. Layer thickness and internal heterogeneity significantly affect the depth and distribution of cracks during . In thicker layers exceeding 5 cm, accumulated shrinkage stresses propagate cracks to greater depths, often penetrating the full layer thickness, whereas thinner layers limit penetration and yield shallower fissures. Heterogeneity, such as variations in or , induces uneven gradients that can localize stress and alter crack paths; additionally, overlying bodies or vegetation cover impedes uniform , thereby suppressing or distorting crack development in affected areas. Biological influences modify the mechanics of desiccation cracking by interfering with and stress distribution. Microbial activity, such as through microbially induced precipitation, can bind particles and reduce tensile stresses, thereby inhibiting crack formation or narrowing existing fissures. Similarly, root penetration from vegetation disrupts uniform shrinkage by channeling stresses and creating preferential pathways, which may redirect or limit crack growth. Quantitative insights from experiments reveal systematic relationships governing crack spacing in relation to dynamics. The spacing SS between cracks approximates Sk/ES \approx k / \sqrt{E}
Add your contribution
Related Hubs
User Avatar
No comments yet.