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

A cryoseism, ice quake or frost quake,[1][2][3][4] is a seismic event caused by a sudden cracking action in frozen soil or rock saturated with water or ice,[5] or by stresses generated at frozen lakes.[6] As water drains into the ground, it may eventually freeze and expand under colder temperatures, putting stress on its surroundings. This stress builds up until relieved explosively in the form of a cryoseism.[1][7] The requirements for a cryoseism to occur are numerous;[1][2] therefore, accurate predictions are not entirely possible and may constitute a factor in structural design and engineering when constructing in an area historically known for such events.[5] Speculation has been made between global warming and the frequency of cryoseisms.[8]

Effects

[edit]

Cryoseisms are often mistaken for minor intraplate earthquakes.[5][9] Initial indications may appear similar to those of an earthquake with tremors, vibrations, ground cracking and related noises,[4] such as thundering or booming sounds.[7] Cryoseisms can, however, be distinguished from earthquakes through meteorological and geological conditions.[5] Cryoseisms can have an intensity of up to VI on the Modified Mercalli Scale.[5] Furthermore, cryoseisms often exhibit high intensity in a very localized area,[4] in the immediate proximity of the epicenter,[9] as compared to the widespread effects of an earthquake.[5] Due to lower-frequency vibrations of cryoseisms,[10] some seismic monitoring stations may not record their occurrence.[9] Cryoseisms release less energy than most tectonic events.[11] Since cryoseisms occur at the ground surface they can cause effects right at the site, enough to jar people awake.[4]

Some reports have indicated the presence of "distant flashing lights" before or during a cryoseism, possibly because of electrical changes when rocks are compressed.[7] Cracks and fissures may also appear as surface areas contract and split apart from the cold.[4][9] The sometime superficial to moderate occurrences may range from a few centimeters to several kilometers long, with either singular or multiple linear fracturing and vertical or lateral displacement possible.[5]

Occurrences

[edit]

Glacial cryoseisms

[edit]

A glacial cryoseism or glacial ice quake is a non-tectonic seismic event of the glacial cryosphere. A large variety of seismogenic glacial processes arising from internal, ocean calving, or basal processes have been identified and studied.[12][13] Very large calving events in Greenland and Antarctica have been observed to generate seismic events of magnitude 5 or larger.[14] Extremely large icebergs can also generate seismic signals that are observable at distances up to thousands of kilometers when they collide or grind across the ocean floor.[15] Basal glacial motion be enhanced due to water accumulation underneath a glacier sourced from surface or basal ice melt. Hydraulic pressure of subglacial water can reduce the friction at the bed, allowing the glacier to suddenly shift and generate seismic waves.[10][16] This type of cryoseism can be very brief, or may last for many minutes.[8]

Location

[edit]

United States

[edit]
US States with reported cryoseisms

Geocryological processes were identified as a possible cause of tremors as early as 1818.[1][5] In the United States, such events have been reported throughout the Midwestern, Northern and Northeastern United States.[1][7][17]

Canada

[edit]

Cryoseisms also occur in Canada,[1][2] especially along the Great Lakes/St. Lawrence corridor, where winter temperatures can shift very rapidly.[18][19] They have surfaced in Ontario, Quebec, Alberta and the Maritime Provinces.[18][20][21]

Other places

[edit]

Glacier-related cryoseism phenomena have been reported in Alaska,[22] Greenland,[23] Iceland (Grímsvötn),[24] Finland,[25] Ross Island,[11] and the Antarctic Prince Charles Mountains.[26]

Precursors

[edit]

There are four main precursors for a frost quake cryoseism event to occur:[1][2]

  1. A region must be susceptible to cold air masses
  2. The ground must undergo saturation from thaw or liquid precipitation prior to an intruding cold air mass
  3. Most frost quakes are associated with minor snow cover on the ground without a significant amount of snow to insulate the ground (i.e., less than 6 inches (15 cm))
  4. A rapid temperature drop from approximately freezing to near or below −18 °C (0 °F), which ordinarily occurred on a timescale of 16 to 48 hours.[1]

Cryoseisms typically occur when temperatures rapidly decrease from above freezing to subzero,[4][9] and are more than likely to occur between midnight and dawn (during the coldest parts of night).[1][5] However, due to the permanent nature of glacial ice, glacier-related cryoseisms may also occur in the warmer months of summer.[10] In general, cryoseisms may occur 3 to 4 hours after significant changes in temperature.[27] Perennial or seasonal frost conditions involved with cryoseisms limit these events to temperate climates that experience seasonal variation with subzero winters. Additionally, the ground must be saturated with water, which can be caused by snowmelt, rain, sleet or flooding.[5] Geologically, areas of permeable materials like sand or gravel, which are susceptible to frost action, are likelier candidates for cryoseisms.[5] Following large cryoseisms, little to no seismic activity will be detected for several hours, indicating that accumulated stress has been relieved.[27]

See also

[edit]

References

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

Cryoseism

View on Grokipedia
from Grokipedia
A cryoseism, also termed a frost quake or ice quake, constitutes a non-tectonic seismic event arising from the abrupt fracturing of water-saturated or rock induced by rapid freezing during intense cold snaps. This process occurs when or , previously unfrozen, expands by approximately 9% upon into , generating thermal stresses that exceed the material's tensile strength and culminate in cracks propagating through the subsurface. Unlike tectonic earthquakes driven by lithospheric plate motions, cryoseisms stem directly from cryogenic volume changes, producing audible booms, localized ground tremors, and occasionally superficial fissures up to several centimeters wide, though structural damage remains negligible. These events necessitate specific preconditions: a saturated subsurface from antecedent or thaw, followed by a precipitous plunge—often exceeding 20°F (11°C) within hours—to below 0°F (-18°C), with minimal insulating cover to facilitate extraction. Cryoseisms manifest predominantly in mid-latitude to high-latitude regions, including the northeastern and , , , , and Arctic locales like , where perennial or seasonal prevails. Empirical records, such as long-term seismic monitoring in terrains, document thousands of such micro-events annually, correlating their frequency with diurnal freeze-thaw cycles and thermal contraction in ice-rich ground. While often misidentified as minor earthquakes by residents due to similar auditory and vibrational signatures, cryoseisms pose no akin to plate-boundary quakes and serve instead as indicators of cryospheric dynamics. Peer-reviewed analyses underscore their utility in probing stability and ground ice content, with datasets exceeding 100,000 events revealing patterns tied to environmental thermal forcing rather than anthropogenic influences. Reports of heightened occurrences in recent decades align with episodic variability, though systematic trends require further instrumental validation beyond anecdotal public observations.

Definition and Characteristics

Physical Properties

Cryoseisms generate seismic signals characterized by high-frequency content, typically in the range of 10–20 Hz, with waveforms that resemble those of shallow tectonic earthquakes but are dominated by energy. These events originate from near-surface sources, often within the top few meters of or , due to the cryogenic fracturing mechanism confined to the frost penetration depth. The magnitudes of cryoseisms are generally low, rarely exceeding local magnitude (ML) 2 on seismological scales, though exceptional cases in regions like the East European platform have reached ML 5.0–5.3, associated with large-scale cracking in . Event durations are brief, lasting seconds, and produce localized ground shaking with minimal horizontal displacement, often accompanied by audible low-frequency booms or sharp cracks audible up to several kilometers away. Physically, cryoseisms result from the expansion of freezing , which increases by approximately 9%, generating shear stresses that exceed the tensile strength of saturated or ice-rich sediments, leading to brittle and crack . Surface manifestations include vertical fissures several centimeters wide and up to a meter deep, with ejected heaved in small mounds, distinguishing them from deeper tectonic ruptures. These properties reflect the event's shallow, volumetric nature rather than slip along fault planes.

Distinction from Tectonic Earthquakes

Cryoseisms differ fundamentally from tectonic earthquakes in their causative mechanisms, as the former arise from the rapid freezing and volumetric expansion of water within saturated soils, sediments, or , generating tensile stresses that fracture the ground without any involvement of . In contrast, tectonic earthquakes stem from the sudden release of accumulated elastic along faults, driven by the relative motions of lithospheric plates. This cryogenic process in cryoseisms typically requires antecedent saturation from or followed by abrupt temperature drops below -20°C (-4°F), conditions absent in tectonic events. Physically, cryoseisms are confined to extremely shallow depths, often less than 1-5 meters, producing localized cracks and low-magnitude seismic signals (usually <2.0 on the local magnitude scale) that dissipate rapidly with distance. Tectonic earthquakes, however, originate at depths ranging from shallow crustal levels to tens of kilometers and can achieve magnitudes exceeding 7.0 or higher, propagating elastic waves globally via established seismic networks. Cryoseismic events lack the precursory strain buildup and fault-plane solutions characteristic of tectonic quakes, instead exhibiting emergent seismic waveforms tied to thermal contraction rather than shear failure. These distinctions enable differentiation through contextual analysis: cryoseisms cluster in periglacial or seasonally frozen regions during winter cold snaps, uncorrelated with active fault zones, whereas tectonic earthquakes align with plate boundaries and exhibit no seasonal bias. While both may produce audible booms or minor ground fissuring, cryoseisms rarely cause structural damage beyond superficial heaving and do not trigger tsunamis or aftershock sequences typical of tectonic ruptures.

Mechanisms and Causes

Freezing-Induced Expansion

The primary mechanism underlying freezing-induced expansion in cryoseisms involves the phase transition of pore water in saturated soils or shallow bedrock during rapid temperature drops below 0°C. When groundwater or soil moisture freezes abruptly, it undergoes a volumetric expansion of approximately 9%, as the density of ice (about 917 kg/m³) is lower than that of liquid water (1000 kg/m³ at 0°C), forcing the material to occupy greater space within confined pore spaces. This expansion generates localized hydrostatic pressures that can reach tens to hundreds of megapascals, far exceeding the typical tensile strength of frozen soils (often 1-10 MPa) or unconsolidated sediments. In fine-grained soils like silt or clay, which retain water via capillary action, unfrozen water migrates toward the advancing freezing front through cryosuction—a process driven by chemical potential gradients and vapor diffusion—leading to the formation of segregated ice lenses. These lenses, typically 1-5 cm thick, accumulate ice volume beyond simple in-place freezing, amplifying uplift pressures up to 0.1-1 MPa per lens layer and stacking vertically to heights of several centimeters over hours to days. The confined growth of these lenses within the soil matrix builds shear and tensile stresses, particularly in non-frost-susceptible materials lacking drainage, until brittle failure occurs along pre-existing weaknesses or new fractures. The sudden fracturing releases stored elastic strain energy as compressional (P) and shear (S) waves, producing audible booms and ground vibrations equivalent to earthquakes of local magnitude (ML) 0.5-2.5, with epicenters shallow (less than 10 m depth) and rupture areas on the order of 10-100 m². Empirical models simulate this by equating expansion-induced stress (σ = ΔV / V × K, where K is bulk modulus) to fracture criteria, such as Griffith's theory for tensile failure when σ > σ_c (critical stress). While contraction contributes in some cases, expansion dominates in water-saturated substrates, as evidenced by field observations correlating events with contents above 20-30% by weight.

Required Environmental Conditions

Cryoseisms necessitate or rock saturated with , typically from recent rainfall, , or a shallow table, which supplies the liquid that expands upon freezing and exerts fracturing pressure. This high content—often near saturation in the upper layers—ensures sufficient ice lens formation or pore expansion, with volume increasing by approximately 9% as it solidifies. A rapid temperature plunge is required, generally from above 0°C to below -10°C within hours, such as during an overnight cold snap, to induce near-instantaneous freezing of the unfrozen or partially frozen ground. This abrupt shift, common in the season's first deep freeze, maximizes the differential stress between expanding and surrounding materials, often peaking between midnight and dawn when is strongest. Minimal snow cover—ideally thin or absent—is crucial, as thicker accumulations insulate the ground and slow the drop, preventing the sudden crystallization needed for seismic release. These conditions prevail in periglacial or transitional zones with seasonal thaw-freeze cycles, where prior mild weather allows moisture accumulation before arctic air masses arrive, rather than in continuously permafrosted areas with limited liquid water availability.

Types of Cryoseisms

Periglacial Frost Quakes

Periglacial frost quakes represent a subtype of cryoseism occurring in environments with pronounced seasonal freeze-thaw cycles, typically in mid-latitude regions lacking continuous but subject to deep winter penetration. These events arise from the sudden expansion of within saturated near-surface soils during rapid cooling, where unfrozen pore transitions to , increasing in volume by approximately 9% and exerting tensile stresses that the frozen ground. The fracturing releases stored as seismic waves, producing shallow, non-tectonic tremors distinct from deeper cryogenic processes in . Essential preconditions include antecedent soil saturation from rainfall, snowmelt, or poor drainage—often in fine-textured soils like silts and clays that impede drainage—and a subsequent sharp temperature decline, typically exceeding 20°C within hours, from near or above 0°C to below -15°C. This rapid freeze-thaw transition generates pore pressures that surpass the material's fracture toughness, estimated at 0.1–1 MPa for ice-soil mixtures, leading to crack propagation at depths of 0.3–1 meter. Unlike thermal contraction cracking in established permafrost, which dominates winter cryoseisms there, periglacial variants emphasize volumetric expansion during initial autumn or early winter freeze-up, with minimal influence from overlying snow insulation. Manifestations include explosive booms, rumbles, or sharp cracks audible up to several kilometers, coupled with localized ground vibrations felt indoors but rarely registering beyond magnitude 1.0–2.5 on seismic scales due to their superficial sources and low energy release. Surface effects may comprise small fissures (1–10 cm wide, meters long) or heaved soil mounds, though structural damage is negligible absent amplification by loose substrates. Seismic signatures feature emergent P- and S-waves with dominant energy, confirming shallow origins via array analysis. Documented instances cluster in North American and Midwest regions, such as and during the January 2019 polar vortex, where temperatures fell to -30°C after wet thaws, yielding widespread reports of shaking and noises without tectonic precursors. In , events occurred in northern Finland's wetlands amid the 2022–2023 extreme cold, with seismic arrays detecting clusters tied to organic-rich, waterlogged soils. These quakes underscore vulnerability in expanding urban-periglacial interfaces, where climate variability may intensify freeze-thaw extremes, though empirical links to long-term trends remain provisional pending refined modeling.

Glacial and Permafrost Cryoseisms

Glacial cryoseisms, also known as glacial earthquakes or large-scale icequakes, arise from dynamic processes within systems, including iceberg calving at marine-terminating fronts, enhanced basal sliding over , and frictional interactions at the glacier bed. These events generate long-period surface waves detectable globally, with magnitudes often exceeding 4.0, distinguishing them from smaller, localized icequakes caused by superficial formation or compaction. In , such events cluster at the ice sheet's outlet glaciers, correlating with seasonal velocity peaks and tidal influences at calving margins. examples, like those at the Whillans Ice Stream, involve stick-slip motion releasing stored during rapid sliding episodes. Permafrost cryoseisms, conversely, stem from thermal contraction and fracturing within the seasonally thawing active layer overlying perennially frozen ground, where rapid cooling induces tensile stresses that exceed the material's , propagating cracks into underlying . These events produce short-duration signals (1-30 seconds) in the 1-30 Hz frequency band, dominated by surface waves from shallow sources near the surface. In Svalbard's Adventdalen valley, passive seismic arrays recorded clusters of such cryoseisms during extreme cold spells, linked to contraction in water-saturated sediments and ice-rich soils, with epicenters aligned along valleys prone to thermal disequilibrium. Unlike glacial variants, permafrost cryoseisms remain low-magnitude (typically <2.0) and are confined to proximal distances, reflecting brittle failure in fine-grained, ice-cemented substrates rather than bulk ice dynamics. Both types require subzero temperatures and moisture availability—pore water in permafrost active layers or subglacial hydrology in glaciers—but differ in scale and detectability: glacial events enable remote monitoring via global networks like GLISN, revealing climate-driven acceleration in calving rates, while permafrost cryoseisms demand local arrays due to their attenuation with depth and distance. In regions of discontinuous permafrost transitioning to glacial forelands, hybrid mechanisms may occur, such as ice-wedge cracking amplified by glacial till saturation.

Historical Background

Early Observations

One of the earliest documented observations of a cryoseismic event occurred in 1819, when American geologist Edward Hitchcock reported a singular linear crack in the ground near Deerfield, Massachusetts, which he attributed to the rapid freezing of saturated soil following a thaw. Hitchcock described the feature in a letter published in the American Journal of Science, noting its resemblance to tectonic fissures but linking it causally to frost action without evidence of seismic instrumentation. This account, from a saturated clay-rich soil after mild weather, marked an initial scientific distinction between frost-induced cracking and true earthquakes, though such events were likely underreported prior due to their shallow, localized nature and lack of widespread monitoring. Similar anecdotal reports of explosive ground noises and cracks during abrupt winter temperature drops emerged in the northeastern United States around the same period, often misidentified as minor earthquakes by lay observers. In Europe, particularly Eastern Europe and Russia, frost quakes were noted sporadically from the early 19th century onward, with accounts of ground upheavals in waterlogged terrains during rapid cooling events, though systematic documentation lagged behind North American records. These pre-instrumental observations relied on eyewitness descriptions of audible booms and superficial fissures, typically 1-10 meters long and shallow, occurring in unglaciated or recently thawed soils without snow cover to insulate against freezing. Prior to the mid-19th century, cryoseisms evaded formal classification due to the absence of seismographs and prevailing attribution to supernatural or unexplained causes in non-scientific chronicles, limiting verifiable data to qualitative field notes from geologists like Hitchcock. Empirical evidence from these accounts consistently highlighted prerequisites such as antecedent precipitation saturating the subsurface, followed by air temperatures plummeting below -10°C, inducing volumetric expansion of ice (approximately 9%) and tensile failure in the host material. Such early insights, while rudimentary, laid groundwork for later mechanistic understanding by emphasizing cryogenic over tectonic origins.

Scientific Development and Terminology

The term cryoseism originates from the combination of the Greek prefix kryos, meaning "cold" or "frost," and seismos, meaning "earthquake," reflecting seismic-like disturbances induced by rapid freezing of water-saturated substrates. Alternative designations include frost quake and ice quake, which emphasize the cryogenic mechanism over tectonic origins, though cryoseism serves as the primary scientific nomenclature for non-tectonic events involving cracking in frozen soil, rock, or ice. Early scientific observations of cryoseismic phenomena trace to 1819, when American geologist Edward Hitchcock documented ground fissures and explosive sounds attributed to frost action in a letter published in the American Journal of Science, marking one of the earliest North American reports distinguishing such events from conventional earthquakes. Formal conceptualization advanced in the mid-20th century amid growing periglacial geomorphology studies, with cryoseisms identified as distinct from glacial icequakes or tectonic seismicity due to their reliance on volumetric expansion from ice formation in pore spaces. By 1980, David E. Howell provided a seminal definition in seismological literature, characterizing cryoseisms as non-tectonic shocks arising from freezing in ice-soil or ice-rock matrices, capable of occurring in both perennial permafrost and seasonally frozen terrains, with magnitudes typically below 3.0 on the Richter scale. Subsequent developments in cryoseismology, including long-term seismic arrays and thermal stress modeling, have refined mechanisms, linking events to rapid temperature drops exceeding 20°C and confirming their prevalence in mid-latitude regions with shallow groundwater. These efforts underscore cryoseisms' role in broader cryospheric dynamics, distinct from endogenic seismic processes.

Geographical Distribution

North American Occurrences

Cryoseisms occur across northern and central regions of North America, particularly where rapid drops in temperature to below freezing follow periods of soil saturation from above-freezing weather or precipitation. In Canada, they are most frequently reported in southern and , with extensive documentation from the winters of 2013–2014 and 2014–2015. Occurrences ranged geographically from , in the west to Montreal, Quebec, in the east, and from southward to approximately 200 km northward. A study analyzing social media reports identified two primary frostquake clusters during these periods: one centered on the Greater Toronto Area and another in eastern Wisconsin, representing the first large-scale documented events in central Canada and adjacent U.S. regions. Specific instances include a notable event on January 3, 2014, affecting and parts of eastern Canada, where sudden cracking sounds and ground vibrations were widely reported amid extreme cold following mild conditions. Further reports emerged in eastern and southern in January 2015, linked to similar meteorological triggers. In the United States, cryoseisms have been observed in Midwestern, Great Lakes, and Northeastern states, including , , , , , and . During the 2013–2014 winter, social media documented events in , , , and , highlighting underreported seismic activity in frozen soils. In January 2024, frost quakes rattled the area in during a sharp temperature plunge. experiences them typically during the season's first intense cold snap, with reports from areas like Caribou. Analysis of historical data has confirmed initial recordings in seven U.S. states, often along the corridor conducive to saturated ground freezing. These events remain challenging to quantify precisely due to their shallow, low-magnitude nature (typically below 2.0), which evades standard seismic networks but is captured through anecdotal and citizen reports.

European and Other Regions

Cryoseisms have been documented in northern Europe, particularly in Finland, where extreme cold snaps have triggered clusters of events in water-saturated wetlands and urban areas. In January 2016, 26 frost quakes occurred within a seven-hour period in the Oulu region, marking one of the highest recorded concentrations of such events in a short timeframe, as analyzed through seismic data. Similar activity was observed during the extreme winter of 2022–2023 in northern Finland, with seismic events linked to rapid freezing in peatlands, producing both low-frequency quakes (10–20 Hz) and high-frequency tremors (120–180 Hz). These incidents highlight vulnerabilities in sub-Arctic European environments, where thawing followed by sudden refreezing exacerbates ground instability. Historical records indicate rarer cryoseismic activity in Eastern Europe and Russia since the 19th century, often misidentified as minor earthquakes due to their seismic signatures. Observations within the East-European Platform, encompassing parts of Russia and surrounding areas, describe frost quakes as distinct from tectonic events, driven by cryogenic cracking in frozen soils. Such reports remain sporadic, with limited instrumental confirmation compared to modern Finnish cases, underscoring the challenges in distinguishing cryoseisms from other seismic noises in permafrost-adjacent zones. Outside Europe, cryoseism reports are scarce and primarily anecdotal, with potential occurrences tied to periglacial conditions in Siberian Russia or other high-latitude Asian regions, though no large-scale verified events match the density seen in Finland or North America. These areas feature extensive permafrost, which could facilitate similar freezing-induced ruptures under rapid temperature drops, but documentation relies on historical or indirect evidence rather than systematic monitoring.

Notable Events and Case Studies

Pre-20th Century Reports

One of the earliest documented reports of a cryoseism occurred in 1819 near Deerfield, Massachusetts, where American geologist Edward Hitchcock observed a linear fissure approximately 100 feet long and several inches wide in the frozen ground, accompanied by a rumbling sound, following a rapid temperature drop. Hitchcock, then principal of Deerfield Academy, attributed the disruption to the expansion of freezing water in the soil, distinguishing it from tectonic activity based on the absence of typical seismic precursors and its localization in saturated, frost-susceptible terrain. This account, published in the American Journal of Science, represents the first North American description explicitly linking ground cracking to cryogenic processes rather than earthquakes. In Europe, particularly in the East European platform regions like Russia, anecdotal historical descriptions from the 19th century reference similar frost-induced seismic-like events in areas such as Moscow and Tver, often misidentified as minor earthquakes due to loud cracking noises and ground tremors during severe cold snaps without snow cover. These reports, drawn from local chronicles and early seismic observations, highlight cryoseisms in clay-rich or water-saturated soils under abrupt sub-zero conditions, though systematic differentiation from true seismicity emerged only later. Pre-19th century accounts remain elusive, likely conflated with broader winter phenomena or omitted from records lacking instrumental verification.

Modern Recorded Events

In central Canada, frost quakes were documented on a large scale during the winters of 2013–2014 and 2014–2015, with social media reports identifying occurrences across southern and , from Windsor to and southward. These events marked the first extensive modern documentation of the phenomenon in the region, triggered by rapid temperature drops following above-freezing conditions and soil saturation. On January 6, 2015, a frost quake shook Montreal's West Island, producing audible booms and vibrations that residents mistook for explosions or structural failures, amid temperatures plummeting to -20°C (-4°F) after mild weather. Similar reports emerged in Toronto and southern Ontario in early January 2014, where extreme cold snaps caused ground cracks and explosive sounds in saturated soils. In Ottawa, frost quakes in February 2022 cracked lawns and rattled homes, with visible fissures up to several centimeters wide forming overnight as groundwater froze rapidly. In the United States, cryoseisms occurred in on January 30, 2019, during a polar vortex with temperatures below -30°C (-22°F), where residents reported bangs, knocks, and booms consistent with ground cracking in wet, unfrozen soils. Comparable events affected the area in January 2024, generating small tremors and loud pops amid record cold following snowmelt. In , Canada, seismic networks recorded lake icequakes on January 1, 2015, with events reaching magnitudes up to 2.0, attributed to thermal contraction of expanding ice sheets rather than soil freezing, distinguishing them from typical periglacial cryoseisms. Instrumental monitoring has captured extensive cryoseismic activity in permafrost regions, such as Adventdalen, , where seismic stations from 2004 to 2021 detected over 100,000 events, featuring high-frequency, short-duration tremors linked to ground thermal stress in seasonally frozen layers. These records confirm cryoseisms' prevalence in high-latitude environments with adequate moisture and rapid cooling, often below -20°C (-4°F), though magnitudes rarely exceed 2.0 and damage remains minimal.

Precursors and Detection Methods

Meteorological Precursors

Cryoseisms typically occur following specific meteorological conditions that prime the ground for sudden expansion and fracturing upon freezing. The soil must first become saturated with water, often from recent precipitation such as rain, snowmelt, or flooding, which fills pore spaces and creates pressure potential during phase change. This saturation is critical, as the volume expansion of water turning to ice—approximately 9%—generates the tensile stresses leading to seismic-like cracks. A second precursor involves minimal snow cover on the surface, which otherwise acts as insulation preventing rapid heat loss from the soil. Without this protective layer, underlying moist ground cools more quickly and deeply during cold snaps. The triggering event is a rapid and extreme drop in air temperature, often to below -20°C (-4°F) or colder, following the saturation phase; this swift freeze causes near-instantaneous expansion in unfrozen water pockets, producing audible booms and ground vibrations. Such conditions are most common in regions susceptible to Arctic air outbreaks, where advection of polar air masses displaces milder weather abruptly. These precursors align with observed events, such as those in the Great Lakes region during January 2019, where pre-event thaws saturated soils before subzero plunges, or in central Canada in late 2019, where similar rapid cooling after wet periods led to widespread reports. Empirical data from seismographs and eyewitness accounts confirm that cryoseisms rarely precede these combined factors, underscoring their role in causal sequences rather than mere correlations.

Seismic and Instrumental Detection

Cryoseisms generate shallow, low-magnitude seismic waves from the rapid expansion and cracking of freezing water-saturated soils or ice, which can be detected by seismometers or geophone arrays deployed locally or within regional networks. These signals often feature emergent onsets, high-frequency content (typically 1–50 Hz), and shorter durations compared to tectonic earthquakes, allowing differentiation through waveform analysis. In Alberta, Canada, a series of lake icequakes on January 1–2, 2018, at sites including Lac Ste. Anne and Pigeon Lake were recorded by the Alberta Geological Survey's regional seismic stations, exhibiting magnitudes around M_L 2.0 and reduced high-frequency power relative to natural earthquakes, consistent with cryoseismic origins tied to thermal contraction. Similarly, passive seismic monitoring in Adventdalen, , employs two-dimensional arrays of vertical-component geophones to isolate transient cryoseismic signals from ambient noise via filtering and stacking techniques. Recent deployments in Finland's wetlands, such as at and from November 2022 to April 2023, used seismic arrays alongside soil temperature sensors to capture hundreds of events, including "frost quakes" with tectonic-like waveforms and "frost tremors" showing irregular patterns akin to lake or sea ice cracking, with peak intensities reaching Modified Mercalli Intensity V. Magnitudes for such soil or ice-related cryoseisms generally range from negative values to around 2.0, though detection thresholds depend on proximity, as weaker events may not propagate far enough for remote recording. Distinguishing cryoseisms from microseisms, wind-induced vibrations, or other cryogenic sources poses challenges, often addressed through high-pass filtering (>1 Hz), spectral analysis, and correlation with meteorological data like rapid temperature drops. Emerging automated methods, including against known cryoseismic signatures and for spectrogram classification, enable systematic reconnaissance in and regions.

Effects and Impacts

Geological and Structural Consequences

Cryoseisms induce superficial fracturing in water-saturated s and rocks where rapid freezing causes ice expansion, typically by about 9% in , leading to tensile stresses that exceed the material's . These fractures are generally shallow, penetrating only centimeters to a few meters into the subsurface, and can span several meters laterally, resulting in visible ground cracks that alter local soil cohesion and permeability. Such disruptions may contribute to minor slope instability or enhanced in affected areas during subsequent thaws, though long-term geological reconfiguration remains negligible compared to tectonic processes. Structurally, the low-magnitude ground motion from cryoseisms—often registering below magnitude 1 on seismographs—rarely inflicts significant damage to , as energy dissipates rapidly with distance. Proximal effects are limited to transient vibrations that may rattle windows or displace loose objects, with documented structural impacts confined to isolated cases of superficial foundation cracks or pavement fissures in silty s prone to heaving. For instance, light damage to nearby buildings has been attributed to cryoseisms in extreme cold snaps, but no widespread failures or injuries have been verified in peer-reviewed records. Preventive measures, such as drainage improvements, mitigate risks in vulnerable regions like the .

Auditory and Perceptual Phenomena

Cryoseisms produce distinctive auditory effects characterized by sudden, explosive noises resulting from the rapid expansion and cracking of frozen soil or . These sounds are commonly described as loud booms, sharp cracks, or popping noises, akin to the of a nearby or small . In some instances, the noise manifests as a low rumbling, resembling distant thunder propagating through the ground. Such auditory phenomena typically occur during the coldest hours, often between and early morning, when contraction peaks and exacerbates the from ice formation. Human perception of these events is frequently marked by surprise and disorientation due to their abrupt onset and intensity, leading observers to initially attribute them to anthropogenic sources like blasting or vehicular impacts. The sounds can propagate variably depending on local and atmospheric conditions, sometimes traveling several kilometers and evoking a of ground that amplifies the perceptual alarm. Reports from affected regions, such as the U.S. Midwest and Northeast, document instances where residents mistook cryoseismic booms for seismic activity, prompting erroneous emergency responses or seismic network alerts until meteorological context clarified the cause. This misperception underscores the phenomenon's superficial similarity to tectonic earthquakes in auditory and minor vibratory cues, despite lacking the deeper rupture mechanisms of true .

Environmental and Climatic Context

Relation to Weather Extremes

Cryoseisms are intrinsically linked to extreme cold weather events characterized by rapid temperature declines, particularly when air temperatures plummet from above freezing to well below zero in a short period, often exceeding 15–20°C (27–36°F) drops within hours. These conditions facilitate the sudden expansion of ice in water-saturated soils, generating the seismic-like cracks and booms diagnostic of the phenomenon. Such rapid freezes are most common during outbreaks or disruptions, where cold air masses advect southward, exposing previously thawed or wet ground to subzero conditions without insulating snow cover. Scientific analyses indicate that cryoseisms require not only low absolute temperatures—typically below -10°C (14°F)—but also a precipitous rate of cooling, such as 1°C per hour or faster, to induce thermal stresses surpassing the of near-surface materials. This is exacerbated in regions with high from antecedent rain, snowmelt, or thaws, as seen in events during Alberta clippers or intensified cold snaps following mild periods. For instance, frost quakes reported in the U.S. Midwest and Northeast during 2024 arctic blasts correlated with ground temperatures dropping rapidly after minimal insulation, leading to widespread cracking in saturated clays and silts. While cryoseisms do not occur in every extreme cold event, their incidence spikes in areas prone to freeze-thaw cycles amplified by weather extremes, such as continental interiors during stratospheric weakenings that propel frigid air equatorward. Observations from Maine's geological surveys confirm that these events cluster around to dawn hours in winter, coinciding with diurnal cold peaks in prolonged outbreaks, and are absent in gradual coolings or deep scenarios that buffer soil freezing. Unlike tectonic , cryoseisms thus serve as indicators of localized cryogenic extremes rather than broader climatic shifts, with magnitudes rarely exceeding 2–3 on seismic scales but capable of audible booms propagating over kilometers. Cryoseisms occur episodically in mid-latitude and high-latitude regions with cold winters, typically during the first intense cold snaps of the season when saturated soils or undergo rapid freezing, often 3 to 4 hours after air temperatures plummet below -15°C (-5°F). Frequencies vary locally but remain low overall, with events concentrated in areas like the , southern Canada, and where antecedent wet conditions from rain or precede sharp freezes. Long-term seismic monitoring in Adventdalen, , from 2016 to 2021 detected tens of thousands of cryoseismic events, primarily during periods of high thermal stress in ice-rich , with peak activity in and magnitudes generally below 1.0. Similar monitoring in northern Finland's wetlands during the 2022–2023 winter recorded multiple events tied to extreme freezing, highlighting higher frequencies in organic-rich, water-saturated terrains. Historical trends are difficult to quantify due to sparse pre-instrumental records and inconsistent detection before modern seismographs, though anecdotal reports date back centuries in regions like . Recent analyses link event timing to shifts in winter air mass frequencies, such as increased incursions of dry polar air masses in southeastern , which have altered since the mid-20th century amid broader changes. No robust global datasets confirm a monotonic increase or decrease, but localized upticks in reported events—such as around in January 2024—coincide with record cold outbreaks following mild, wet periods. Attribution debates center on influences, with causal mechanisms rooted in the physics of expansion (volume increase of ~9% upon freezing) requiring specific precursors: saturation and rapid conductive cooling. Proponents of increased frequency under warming cite greater winter and atmospheric variability, potentially amplifying saturated ground conditions before cold snaps, as observed in sub-Arctic wetlands where events may rise with altered freeze-thaw dynamics. Counterarguments emphasize that hemispheric warming reduces overall cold-day totals and deep freezing depths, limiting opportunities for cryoseisms, with any perceived rise attributable to improved seismic networks and media amplification rather than climatic forcing. Empirical long-term records, like those from , show event clustering tied to interannual temperature variability but no clear upward trajectory linked to anthropogenic trends, underscoring the need for extended monitoring to disentangle detection biases from genuine shifts. Claims of direct climate-driven escalation often appear in non-peer-reviewed outlets and lack quantitative hindcasts, reflecting potential overinterpretation of episodic data.

Misconceptions and Differentiations

Common Confusions with Other Phenomena

Cryoseisms are commonly mistaken for minor earthquakes due to the production of similar seismic vibrations, loud explosive booms, and localized ground jolts that can register on seismographs. This confusion stems from the rapid expansion of freezing water in saturated , which generates shallow seismic waves mimicking the tremors of tectonic events, though cryoseisms lack the deeper hypocenters and aftershocks typical of true earthquakes. For instance, during a 2019 cold snap in the U.S. Midwest, initial reports of shaking in were attributed to earthquakes before meteorological analysis confirmed cryoseismic origins based on the absence of fault-line activity and correlation with subzero temperature drops exceeding 20°F in hours. The auditory phenomena of cryoseisms, including sharp cracking or rumbling noises, are occasionally confused with thunder, sonic booms, or even distant explosions or gunfire, especially when occurring at night in isolated regions. However, these misattributions are less frequent than seismic ones, as the sounds propagate through rather than the atmosphere, producing a more muffled, ground-coupled quality distinct from aerial thunderclaps. Differentiation often requires contextual evidence, such as concurrent extreme cold without barometric pressure changes indicative of storms, and seismic data showing event magnitudes rarely exceeding 2.0 on the with epicenters at depths under 10 meters. In regions with active or , cryoseisms may be erroneously linked to blasting operations, but the irregular timing tied to diurnal freeze-thaw cycles and lack of human scheduling distinguishes them. Peer-reviewed analyses of cryoseismic events, such as those in Canada's zones, emphasize that while initial instrumental readings overlap with low-magnitude , the cryogenic mechanism is confirmed via ground temperature logs and profiles post-event.

Evaluation of Causal Claims

The prevailing causal explanation for cryoseisms attributes them to the sudden expansion of water-saturated soils upon freezing, which induces tensile stresses exceeding the material's fracture strength, thereby propagating cracks and releasing energy as shallow seismic waves. This mechanism is substantiated by field observations correlating event onsets with air temperatures dropping below -10°C after initial soil saturation from prior thaws or precipitation, as documented in long-term seismic arrays in permafrost regions like Adventdalen, Svalbard, where over 20,000 events from 2016–2020 aligned with thermal contraction in ice veins within frozen fissures. Modeling of thermal stress in soil-ice composites confirms that rapid cooling rates of 5–10°C per hour can generate stresses up to 1–2 MPa, surpassing the typical 0.1–0.5 MPa tensile strength of such mixtures and initiating brittle failure near the surface. Instrumental differentiation from tectonic earthquakes reinforces this causality: cryoseismic signals feature high-frequency surface waves (P- and S-wave velocities <1 km/s), epicentral localization within 1–5 km, and depths under 10 m, contrasting with deeper hypocenters (>5 km) and body-wave dominance in plate-boundary events; no shear faulting or sequences typical of elastic rebound occur. Alternative hypotheses, such as cryogenic or gas destabilization, lack empirical support in non-permafrost settings where cryoseisms predominate, as alone fails to produce the observed explosive ruptures without volumetric growth (approximately 9% expansion). Limitations in causal attribution arise from sparse global monitoring, with most data from high-latitude sites potentially overemphasizing dynamics over temperate-zone occurrences driven by episodic saturation; however, waveform inversion and post-event surveys consistently trace cracks to penetration depths of 0.5–2 m, excluding deeper geophysical drivers. Claims linking cryoseism to broader climatic trends, such as intensified freeze-thaw cycles, remain correlative rather than mechanistically proven, as event rarity (magnitudes <2.5) and dependence on localized defy scalable attribution without site-specific validation.

References

  1. https://www.maine.gov/dacf/mgs/hazards/earthquakes/quake-cryoseism.htm
  2. https://tc.copernicus.org/articles/16/2025/2022/
  3. https://www.accuweather.com/en/winter-weather/what-is-a-frost-quake-and-where-do-they-occur/670762
  4. https://www.visualcrossing.com/resources/blog/what-is-frost-quakes-and-cryoseisms/
  5. https://tc.copernicus.org/articles/18/2223/2024/
  6. https://risklayer-explorer.com/report/4
  7. https://www.researchgate.net/publication/225575079_Frost_quakes_as_a_particular_class_of_seismic_events_Observations_within_the_East-European_platform
  8. https://www.researchgate.net/publication/344327700_Frost_Quakes_Crack_Formation_by_Thermal_Stress
  9. https://www.usgs.gov/programs/earthquake-hazards/earthquake-booms-seneca-guns-and-other-sounds
  10. https://www3.ncrn.cornell.edu/passive-seismic-recording-of-cryoseisms-in-adventdalen_Yjo0NToxNQ.pdf
  11. https://cdnsciencepub.com/doi/full/10.1139/cjes-2018-0089
  12. https://cdnsciencepub.com/doi/10.1139/cjes-2018-0196
  13. https://www.researchgate.net/publication/355609887_Long_term_analysis_of_cryoseismic_events_and_associated_ground_thermal_stress_in_Adventdalen_Svalbard
  14. https://www.frontiersin.org/journals/earth-science/articles/10.3389/feart.2022.826961/full
  15. https://link.aps.org/doi/10.1103/PhysRevE.87.032404
  16. https://farmonaut.com/usa/frost-quakes-understanding-new-englands-mysterious-winter-phenomenon-and-climate-impact
  17. https://www.popularmechanics.com/science/environment/a46612675/what-are-frostquakes/
  18. https://www.foxweather.com/learn/cryoseism-winter-earthquakes
  19. https://northernwoodlands.org/outside_story/article/frost-quakes
  20. https://eos.org/research-spotlights/predicting-the-next-big-frost-quake
  21. https://www.firstalert4.com/2025/01/20/frost-quakes-heres-what-you-need-know/
  22. https://tc.copernicus.org/articles/18/2223/2024/tc-18-2223-2024.pdf
  23. https://www.forbes.com/sites/marshallshepherd/2019/02/01/the-deeper-science-behind-sounds-and-flashes-in-frost-quakes/
  24. https://www.intechopen.com/chapters/61739
  25. https://tc.copernicus.org/articles/15/283/2021/
  26. https://ui.adsabs.harvard.edu/abs/2023AGUFM.S43F04.1R/abstract
  27. https://www.popsci.com/story/science/frost-quake-weird-weather/
  28. https://www.researchgate.net/publication/313444438_Frost_Quake_Events_and_Changing_Wintertime_Air_Mass_Frequencies_in_Southeastern_Canada
  29. https://www.accuweather.com/en/winter-weather/what-is-a-frost-quake-ice-quake-cryoseism/1477983
  30. https://link.springer.com/article/10.1134/S1069351310030079
  31. https://www.sciencedirect.com/science/article/abs/pii/S0013795299000927
  32. https://www.cbsnews.com/chicago/news/loud-pops-cold-snap-frost-quake/
  33. https://lifestyle.sustainability-directory.com/area/cryoseism/
  34. https://pubs.geoscienceworld.org/ssa/srl/article-abstract/51/1/15/141705/A-Short-Note-on-Cryoseisms
  35. https://geoskid.wordpress.com/2012/11/26/frost-earthquakes-cryoseisms/
  36. https://tc.copernicus.org/articles/16/2025/2022/tc-16-2025-2022.pdf
  37. https://www.researchgate.net/publication/313398799_Identifying_Frostquakes_in_Central_Canada_and_Neighbouring_Regions_in_the_United_States_with_Social_Media
  38. https://weather.com/news/news/frost-quake-canada-20140106
  39. https://globalnews.ca/news/1740203/the-frost-quakes-have-returned-what-have-we-learned-since-2014/
  40. https://www.latimes.com/nation/nationnow/la-na-nn-frost-quakes-cryoseism-20140206-story.html
  41. https://www.cnn.com/2024/01/19/world/frost-quakes-cold-weather-seismic-phenomenon-scn
  42. https://globalcryospherewatch.org/interesting-events/cryoseisms-in-chicago/
  43. https://www.newscientist.com/article/2373185-dozens-of-frost-quakes-hit-a-finnish-town-in-just-7-hours/
  44. https://www.iflscience.com/frost-quakes-hit-a-city-in-finland-26-times-in-seven-hours-68929
  45. https://geographical.co.uk/science-environment/frost-quakes-are-a-growing-problem-in-finland-and-other-sub-arctic-countries
  46. https://eos.org/articles/frost-quakes-shake-up-finlands-wetlands
  47. https://en.wikisource.org/wiki/The_American_Journal_of_Science/Series_1%2C_Volume_1
  48. https://www.gutenberg.org/files/52663/52663-h/52663-h.htm
  49. https://www.cbc.ca/news/canada/montreal/frost-quake-shakes-montreal-s-west-island-1.2891618
  50. https://www.theglobeandmail.com/news/national/recent-weather-activity-brings-frost-quakes-to-southern-ontario/article16189544/
  51. https://www.cbc.ca/news/canada/ottawa/frost-ice-quake-ottawa-1.6362921
  52. https://wxguys.ssec.wisc.edu/2019/02/11/icequakes/
  53. https://agupubs.onlinelibrary.wiley.com/doi/full/10.1002/2016RG000526
  54. https://tc.copernicus.org/articles/18/2061/2024/
  55. https://www.colorado.edu/engineering/2020/11/16/cu-boulder-researchers-contribute-frost-quake-modeling-research
  56. https://goodmansonconstruction.com/cryoseism-frost-quake/
  57. https://www.accuweather.com/en/weather-news/how-loud-booms-can-fool-people-into-thinking-theres-an-earthquake-when-its-very-cold-2/434337
  58. https://www.ktiv.com/2025/01/21/very-cold-temperatures-created-whats-called-frost-quakes-siouxland/
  59. https://www.britannica.com/science/cryoseism
  60. https://www.worldatlas.com/articles/what-is-a-frost-quake-what-is-an-ice-quake.html
  61. https://www.nbcnews.com/science/science-news/frost-quakes-dropping-temperatures-can-lead-mysterious-booms-rcna69030
  62. https://agupubs.onlinelibrary.wiley.com/doi/abs/10.1029/2020JF005616
Add your contribution
Related Hubs
User Avatar
No comments yet.