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Needle Ice forming in a pile of red clay soil
Needle ice pushing up soil particles
Needle ice is formed of distinct, unconsolidated strands

Needle ice is a needle-shaped column of ice formed by groundwater. Needle ice forms when the temperature of the soil is above 0 °C (32 °F) and the surface temperature of the air is below 0 °C (32 °F). Liquid water underground rises to the surface by capillary action, and then freezes and contributes to a growing needle-like ice column. The process usually occurs at night when the air temperature reaches its minimum.

The ice needles are typically a few centimetres long. While growing, they may lift or push away small soil particles. On sloped surfaces, needle ice may be a factor contributing to soil creep.[1][2]

Alternate names for needle ice are "frost pillars" ("Säuleneis" in German), "frost column", "Spew Ice", "Kammeis" (a German term meaning "comb ice"), "Stängeleis" (another German term referring to the stem-like structures), "shimobashira" (霜柱, a Japanese term meaning frost pillars), or "pipkrake" (from Swedish pipa (tube) and krake (weak, fine), coined in 1907 by Henrik Hesselman).[3]

The similar phenomena of frost flowers and hair ice can occur on living or dead plants, especially on wood.

Formation

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In order for needle ice to form there needs to be a process of ice segregation, which only occurs in a porous medium when supercooled water freezes into existing ice, growing away from the ice/water interface. As water permeates the ice, it becomes segregated into separate pieces of ice in the form of lenses, ribbons, needles, layers or strands of ice.[4]

Needle ice is commonly found along stream banks or soil terraces. It is also found by gaps around stones and others areas of patterned ground. The variety of soil properties also affects where it is found. Places where the soil is much deeper and richer can affect the growth of the ice. Consequently, the deeper the soil, the larger the water content allows it to develop. It can be evidently formed anywhere where underground water is exposed to open (freezing) air.[5]

Needle ice is most suitable in soils with a high silt and organic matter content. Needle ice consists of groups of narrow ice slivers that are up to several centimeters long. Although the literature states that the largest recorded needle ice was at 10 cm in length,[6] specimens 15-20 cm in length have been observed at Gerðuberg, for example.

Needle ice can sometimes appear to curve or curl

Needle ice grows up slowly from the moist and water-penetrable soil, and melts gradually in the sun. It can vary in appearance but always shows the consistent growth of ice perpendicular to the surface of the ground. Needle ice looks like a series of filamentous crystals, and is straight or curved in shape. It usually forms in the morning when the temperature drops below freezing point (0 °C).[7]

Environmental impacts

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The emergence of needle ice has been recognized as a geomorphic agent of soil disturbance, causing a number of small-scale landforms.[8] Needle ice phenomena play a particularly significant role in patterned ground in periglacial environments.[8]

The growth of needle ice lifts a detached, frozen soil crust riding on top of the layer of ice. When the crust and the ice melt, the soil surface settles back irregularly. This phenomenon is linked to erosion, particularly on streambanks.[8]

Needle ice tends to move rocks in the soil up toward the surface and to shift rocks on the surface into nearby depressions.[9] Depressions caused by needle ice activity are known as needle-ice pans, and lumps caused by needle ice are known as "nubbins".[10]

Plant growth

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Needle ice affects the growth of plants.[8] Seedlings are often heaved to this surface by needle ice. When the ground hardens the stems and roots of the seedling, they are gripped by the soil and then the formation of needle ice is what pushes them up and out the ground. When the needle ice melts, the seedlings do not settle correctly back into the ground causing them to die. Even if the seedlings are partially heaved by the needle ice, they can still die due to root desiccation.[11]

See also

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References

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Further reading

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Revisions and contributorsEdit on WikipediaRead on Wikipedia

Needle ice

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from Grokipedia
Needle ice is a ground-surface ice formation consisting of long, thin, needle-like ice crystals that develop vertically in moist soil when air temperatures fall below freezing while the soil remains unfrozen, typically during transitional periods such as spring and fall nights.[1] These crystals, also known as pipkrake or acicular ice, emerge perpendicular to the ground surface through a process of ice segregation, where unfrozen water migrates via capillary action to the freezing front and solidifies into elongated structures.[2] The formation of needle ice requires specific environmental conditions, including soil moisture content of at least 12-19% silt-clay, a nucleation temperature of -2°C or lower, and rapid moisture supply to the freezing plane, often in loose, porous soils.[3] Growth occurs incrementally as water freezes and expands, entrapping soil particles and creating variable morphologies influenced by factors like freezing depth, soil tension, and thermal properties.[2] Needle ice typically reaches heights of several centimeters, though lengths can vary based on local conditions, and it melts upon warming, often leading to soil heave or disruption.[4] Globally distributed across all continents in cold and temperate regions, needle ice is most prevalent in mid-latitude highlands like the Andes and Rockies, eastern North America, Europe, and East African mountains, with an inverted U-shaped existence domain peaking at higher altitudes in lower latitudes.[3] It plays a significant role in geomorphic processes, such as uplifting and sorting soil particles and small stones during repeated freeze-thaw cycles, contributing to the development of patterned ground features like stone stripes and polygons in periglacial environments.[4] These effects can influence erosion rates, vegetation patterns, and even signal past climate conditions in permafrost zones, with implications for Arctic landscapes and analogous features on Mars.[4]

Physical characteristics

Appearance and structure

Needle ice manifests as clusters of slender, bristle-like ice crystals emerging perpendicularly from the soil surface, creating a spiky, filamentous appearance akin to a dense array of fine needles or threads. These crystals are typically translucent and highly fragile, often growing in loosely interlocked bundles or sheaves that form crunchy, elevated clusters on bare ground. In natural settings, the formations frequently exhibit a "dirty" aspect due to entrained soil particles, with crystals sometimes fusing into ridges or leaving underlying cavities upon partial melting.[5][6][7] The internal structure of needle ice arises from ice segregation processes within soil pore spaces and capillary channels, yielding a porous morphology where unfrozen water migrates and freezes incrementally to elongate the crystals. This results in elongated, columnar forms oriented perpendicular to the ground surface, with variable banding patterns—influenced by mineral particle entrapment and episodic growth phases—often parallel to the surface as horizontal layers. The crystals maintain a low density, approximately 0.2 g/cm³, reflecting their open, segregated architecture rather than solid ice masses.[2][8] Needle ice is distinct from hoar frost, which develops via direct vapor deposition on exposed surfaces without soil involvement, and from frazil ice, which consists of small, irregular crystals forming in turbulent open water rather than through soil-based segregation. These differences highlight needle ice's unique tie to subsurface groundwater dynamics, producing upright, soil-embedded structures absent in atmospheric or aquatic ice types.[6][7]

Size and growth

Individual needle ice formations typically range from 1 to 10 cm in length and 1 to 3 mm in diameter, though in porous soils such as volcanic ash, maximum lengths of several centimeters have been observed, with cumulative heave from repeated formations reaching up to 14 cm.[9][10] Growth of needle ice proceeds incrementally overnight through successive freeze-thaw cycles, with maximum development usually achieved within 8 to 12 hours under suitable conditions, starting after sunset and peaking before sunrise.[9] The dimensions and density of needle ice vary with soil texture; finer-grained soils, such as silts, promote denser arrays of shorter needles due to enhanced capillary action and thermal conductivity, while coarser soils, like sands, allow for longer but sparser formations by permitting greater water migration before interruption.[11][12] The growth process involves distinct phases: initial nucleation occurs at the soil surface where groundwater first freezes into small ice spicules, followed by elongation as additional unfrozen water rises via capillary action and freezes in successive layers atop the existing structure, building the needle upward.[1][9]

Formation

Mechanisms

Needle ice primarily forms through the process of ice segregation, in which soil water in unsaturated zones migrates upward via capillary action toward the cold surface, where it freezes upon reaching the freezing front. This migration is driven by the soil water potential gradient, which arises from the temperature dependence of the freezing point as described by the Clausius-Clapeyron equation, creating a suction that pulls unfrozen water from deeper, warmer layers. The resulting segregated ice grows as discrete needles rather than uniformly within the soil matrix, as the process excludes soil particles and forms vertical channels. The thermodynamic process sustaining needle ice growth involves the release of latent heat during freezing at the ice-soil interface, which locally warms the surrounding soil and maintains a temperature gradient that continues to draw water from unfrozen depths below. This heat release balances the conductive heat loss to the colder surface, allowing prolonged ice segregation even as the surface temperature drops. The efficiency of this process depends on the availability of unfrozen water films around soil particles, which persist below 0°C due to premelting induced by intermolecular forces. A key approximation for the ice growth rate, or heave velocity vv, in needle ice formation derives from the Stefan condition for the moving freezing boundary, balancing conductive heat flux with latent heat of fusion. The heat conducted away from the interface is given by q=kdTdzq = k \frac{dT}{dz}, where kk is the thermal conductivity of the frozen soil (typically 1.5–2.5 W/m·K for silty soils), dTdz\frac{dT}{dz} is the temperature gradient (often 1–10 K/m in surface freezing), and the sign is taken positive for the magnitude. This heat flux equals the latent heat required to freeze the incoming water: ρi[L](/page/L)v\rho_i [L](/page/L) v, where ρi\rho_i is the density of ice (≈917 kg/m³) and LL is the latent heat of fusion (334 kJ/kg). Thus, the heave velocity is
vkρiLdTdz. v \approx \frac{k}{\rho_i L} \frac{dT}{dz}.
This model assumes quasi-steady state, negligible sensible heat in the frozen zone, and sufficient water supply; deviations occur if hydraulic limitations reduce influx. For typical values (k=2k = 2 W/m·K, dTdz=5\frac{dT}{dz} = 5 K/m), vv is approximately 0.1 mm/h, aligned with observed needle growth rates of 0.01–1 mm/h over diurnal cycles.[3] The role of soil pores in needle ice development stems from the Gibbs-Thomson effect, which depresses the freezing point in smaller pores due to curvature-induced pressure, causing initial freezing to occur preferentially in larger pores (radii >10–50 μm in silts). This selective nucleation forms ice-filled channels that propagate upward, excluding finer soil particles and promoting the elongated, needle-like morphology while leaving a network of unfrozen films in smaller pores to facilitate continued water transport. In coarser soils, fewer large pores limit segregation efficiency, resulting in shorter needles.

Required conditions

Needle ice formation necessitates a distinct thermal gradient within the soil profile, where temperatures at depths of approximately 5-10 cm remain above 0°C to maintain a supply of liquid water, while air and soil surface temperatures fall below 0°C, with optimal ranges of -2°C to -5°C promoting efficient freezing at the surface.[13][14] This gradient ensures that unfrozen water can migrate upward via capillary action without the entire soil column solidifying.[15] Soil moisture content plays a pivotal role, requiring adequate levels, typically greater than 13% by volume, to support the upward transport of water; formation can occur in both unsaturated and near-saturated conditions.[16] Optimal soil textures, such as loams and silts with 12-19% silt-clay content, facilitate needle ice growth due to their pore diameters suitable for effective capillary action (generally 0.02-2 mm); coarser sands permit excessive drainage, while finer clays restrict permeability and water movement.[3][16] Microclimatic conditions further enhance formation, including clear skies that allow radiative cooling to rapidly lower surface temperatures, low wind speeds that minimize heat advection and preserve the freezing front, and diurnal cycles featuring daytime thawing to replenish soil moisture.[14][13] These factors collectively create the environmental prerequisites for the process.

Occurrence

Geographical distribution

Needle ice predominantly occurs in mid-latitude temperate zones between approximately 30° and 60° N and S, where seasonal temperature fluctuations facilitate frequent freeze-thaw cycles.[3] A global survey of over 200 studies identified 113 specific sites, revealing concentrations in regions such as the Rocky Mountains and Andes in the Americas, eastern United States, northwest and central Europe, East African mountains, and parts of Asia including Japan.[3] In North America, documented occurrences include the Canadian Rockies and the Appalachian Mountains, while in Europe, it is prevalent in the Alps and Scandinavian forests.[3][17][18] In Asia, needle ice forms in the Siberian taiga and associated highlands, such as the Northern Priokhotye and Okhotsk-Kolyma regions.[19][3] It is most common in periglacial environments, including mountain slopes, tundra margins, and high-altitude plateaus, where fine-grained, moist soils support ice segregation.[3][20] These features align with the lower boundary of permafrost, showing an inverted U-shaped distribution where needle ice appears at progressively higher elevations toward the equator.[3] Conversely, it is rare in tropical lowlands lacking frost and on polar ice sheets dominated by continuous permafrost, limiting soil moisture dynamics.[3] Incidence is highest in areas experiencing 50 to 100 annual freeze-thaw cycles, such as central European sites with 70 to 82 events per year.[3] Terrain plays a key role, with south-facing slopes in the Northern Hemisphere promoting rapid solar thawing after nocturnal freezing, and valleys facilitating cold air pooling to enhance surface cooling.[21][22] These conditions maximize the diurnal temperature gradients essential for needle ice development.[3]

Temporal patterns

Needle ice primarily forms during transitional seasons, such as late fall to early winter and early spring, when soil temperatures remain above freezing while nocturnal air temperatures fall below 0°C, enabling the capillary rise of unfrozen soil moisture into the cooler air.[3] This timing exploits the thermal contrast between the ground and atmosphere, with events most frequent in regions experiencing mild winters without persistent snow cover. For instance, in the Vancouver area of Canada, needle ice occurrence peaks in December and February, aligning with these transitional periods.[3] The process exhibits a pronounced diurnal pattern, with growth initiating at night under clear, calm conditions that promote radiative cooling, typically lasting 8-12 hours until sunrise.[23] Ice segregation accelerates as surface temperatures reach approximately -1°C, drawing water upward until the freezing front stabilizes. By midday, solar radiation and increasing air temperatures cause rapid melting from the needle tips and bases, completing the cycle within a roughly 24-hour period and leaving the soil surface disrupted.[23] Annually, the frequency of needle ice events varies significantly with climate type, reflecting differences in temperature variability and precipitation regimes. In continental climates, such as the Tatra Mountains of southern Poland, up to 70-82 events can occur per year due to frequent freeze-thaw alternations.[3] In contrast, maritime climates experience fewer instances; for example, the Vancouver region averages about 26 events annually, limited by milder winters and higher humidity that reduce nocturnal cooling extremes.[3]

Environmental impacts

On soil and geomorphology

Needle ice formation induces frost heave by the upward growth of ice crystals that displace soil particles vertically, typically resulting in surface elevations of 1-5 cm per freeze-thaw event.[24] This repeated heaving disrupts soil horizons and contributes to cryoturbation, a process of intensive soil mixing that redistributes particles and organic matter across depths of several centimeters to decimeters in periglacial environments. Cryoturbation driven by needle ice enhances soil heterogeneity, promoting the formation of involutions and disrupted layering observable in permafrost-affected profiles.[25] On slopes, the toppling of needle ice upon thawing promotes frost creep, a gradual downslope movement of soil materials at rates typically ranging from 1-10 cm per year, depending on slope angle and soil texture.[26] This creep mechanism, often combined with gelifluction in saturated conditions, leads to the development of characteristic landforms such as solifluction lobes—tongue-shaped accumulations of saturated soil advancing downslope—and terracettes, which are stepped features formed by differential movement along slope contours.[27] These features stabilize slopes over time but can accelerate mass wasting in frost-susceptible fine-grained soils.[28] Over longer timescales, repeated needle ice activity plays a key role in periglacial geomorphology by generating micro-relief patterns, including small sorted circles and stone stripes, through the segregation of finer soil from coarser clasts during cyclic heaving and transport.[29] In laboratory simulations, such patterns emerge after 30-60 freeze-thaw cycles, with stone displacements of approximately 0.1 cm per cycle in low-concentration areas, fostering positive feedback loops that amplify sorting on scales of 1-10 cm.[29] These features contribute to landscape evolution in high-latitude and alpine regions by maintaining dynamic equilibrium between erosion and deposition.[25] Needle ice also alters soil structure by increasing porosity through the expansion and subsequent collapse of ice lenses, which creates macropores and enhances drainage capacity in otherwise compacted layers.[30] Concurrently, the mechanical stress from crystal growth causes aggregate breakdown, fragmenting soil clasts and reducing overall stability, particularly in silty or loamy materials prone to frost action.[30] This dual effect—improved infiltration juxtaposed with heightened susceptibility to downslope failure—underpins the long-term transformation of soil profiles in seasonal frost zones.[31]

On vegetation

Needle ice formation exerts significant direct effects on vegetation by uplifting and uprooting seedlings and small plants through frost heaving, which lifts roots out of the soil and exposes them to desiccation during dry periods or burial upon melting. This process is particularly damaging in fine-textured soils where needle ice columns can reach lengths of 10-50 mm, displacing small vegetation and leading to high mortality rates among shallow-rooted individuals.[12] The disruption caused by needle ice also inhibits seed germination and early establishment by breaking seed-soil contact and altering microtopography, resulting in substantial reductions in seedling survival in alpine environments. Studies in high-elevation meadows indicate that such disturbances contribute to elevated mortality, with needle ice identified as a primary stress alongside soil drought, hindering the successful colonization of new plants.[32] Needle ice impacts vegetation selectively, disproportionately affecting shallow-rooted herbs while favoring deep-rooted perennials that maintain better anchorage against heaving. In alpine tundra settings, this dynamic is evident in communities dominated by resilient species such as sedges, which exhibit lower susceptibility to uprooting compared to more vulnerable forbs and grasses.[12] At the ecosystem level, repeated needle ice activity promotes heterogeneous vegetation mosaics and patch dynamics by creating disturbed microsites that facilitate cyclic turnover in grasslands and forest edges, influencing species composition and community structure over time. This soil disturbance from heaving briefly referenced here underscores the role of needle ice in maintaining biodiversity through localized regeneration opportunities.[33]

On erosion processes

Upon melting, needle ice creates loose, elevated soil aggregates that reduce soil cohesion and increase surface roughness, thereby heightening susceptibility to overland flow erosion.[30] In peatlands, this process can elevate erosion rates by approximately six times on average, with sediment yields reaching up to 15 times higher under certain flow conditions, due to enhanced shear stress (55–85% increase) and the formation of microrills and headcuts that concentrate flow paths.[30] In stream beds and river banks, needle ice incorporates and destabilizes fine sediments, trapping particles during growth and releasing them upon thaw, which promotes bank scour and the export of suspended fines during subsequent low-magnitude flows.[34] This contributes substantially to overall sediment budgets, accounting for 32–43% of total bank erosion through mechanisms such as particle fallout, sediment-laden rivulets, sliding, and toppling failures, with yields up to 4.02 kg m⁻² per event.[34] Post-melt, the fragmented and exposed soil surfaces generated by needle ice facilitate wind erosion, particularly in dry conditions, leading to deflation of fine particles and the development of bare deflation scars or pans within otherwise vegetated areas.[35] Case studies illustrate these effects: in Scottish blanket bogs, such as those in the Moor House area, needle ice-driven surface retreat contributes to annual peat losses averaging around 1.9 cm, though rates vary from 1 to 7 cm year⁻¹ across eroding sites.[36] In the Rocky Mountains' alpine zones, like the Colorado Front Range, needle ice exposes mineral soils on steep pastures, enforcing rill formation through enhanced surface runoff and wind action, which accelerates linear erosion networks.[37] Frost heave associated with needle ice further loosens soil aggregates, priming them for these erosional transports.[30]

References

  1. [PDF] Ground Water in Permafrost Regions An Annotated Bibliography
  2. An Algorithm for Needle Ice Growth - Outcalt - 1971 - AGU Publications
  3. Environmental Limits of Needle Ice: A Global Survey
  4. Ice needles weave patterns of stones in freezing landscapes - PMC
  5. Needle ice formation, induced frost heave, and frost creep
  6. In Cold, Wet Woods, Needle Ice Sprouts | The Outside Story
  7. Needle Ice - Ice Segregation in soil - James R. Carter
  8. https://deepblue.lib.umich.edu/bitstream/handle/2027.42/41665/704_2005_Article_BF02253559.pdf
  9. Advances in understanding the cooling rates and bending of needle ...
  10. DuluthStreams - ice terminology - Lake Superior Streams
  11. How Soil Freezes and Thaws at a Snow-Dominated Forest Site in ...
  12. Needle-Ice Activity and the Distribution of Stem-Rosette Species in a ...
  13. [PDF] Needle Ice
  14. https://doi.org/10.1016/j.coldregions.2018.11.003
  15. https://doi.org/10.1016/S0012-8252(01
  16. First observations on needle ice formation in the sub-Antarctic
  17. https://doi.org/10.1080/00040851.1988.12002661
  18. Effects of Needle Ice on Peat Erosion Processes During Overland ...
  19. (PDF) Needle ice formation, induced frost heave, and frost creep
  20. Needle ice formation, induced frost heave, and frost creep: A case ...
  21. NEEDLE ICE ON DEAD AND ROTTEN BRANCHES
  22. Modeling the Influence of Needle Ice on Slope Morpholithogenesis ...
  23. Periglacial Processes & Landforms in Cold Environments | DP IB ...
  24. Periglacial processes and landforms
  25. Needle Ice - West Valley Naturalists
  26. [PDF] A study of time dependence during serial needle ice events
  27. Climate Change Indicators: Freeze-Thaw Conditions | US EPA
  28. The impact of freeze-thaw processes on a cliff recession rate in the ...
  29. Decadal Variability of Differential Frost Heave on Incipient Sorted ...
  30. Cryogenesis and soil formation along a bioclimate gradient in Arctic ...
  31. Frost for the trees: Did climate increase erosion in unglaciated ...
  32. Solifluction rates, processes and landforms: a global review
  33. Periglacial Landforms - AntarcticGlaciers.org
  34. Ice needles weave patterns of stones in freezing landscapes - PNAS
  35. Disparity in soil erosion processes between freeze-thaw and ...
  36. Seedling demography in an alpine ecosystem
  37. Spatial perspectives in state‐and‐transition models: a missing link to ...
  38. Needle ice processes and sediment mobilization on river banks
  39. Periglacial Vegetation‐Banked Terraces: A Global Survey
  40. [PDF] Erosion in peatlands: Recent research progress and future directions
  41. Soils at the Altitudinal and Northern Treeline: European Alps ...
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