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Snow squall
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A snow squall, or snowsquall, is a sudden moderately heavy snowfall with blowing snow and strong, gusty surface winds.[1] It is often referred to as a whiteout and is similar to a blizzard but is localized in time or in location and snow accumulations may or may not be significant.
Types
[edit]There are two primary types of snow squalls: lake effect and frontal. Both types can strongly reduce visibilities and sometimes produce heavy snowfall.
Lake-effect snow
[edit]When arctic air moves over large expanses of warmer open waters in winter, convective clouds develop which cause heavy snow showers due to the large amount of moisture available. This occurs southwest of extratropical cyclones, with the curved cyclonic wind flow bringing cold air across the relatively warm Great Lakes which then leads to narrow lake-effect snow bands that can produce significant localized snowfall.[2] Whiteout conditions will affect narrow corridors from shores to inland areas aligned along the prevailing wind direction.[3][4] This will be enhanced when the moving air mass is uplifted by higher elevations. The name originates from the Great Lakes area of North America, however any body of water can produce them. Regions in lee of oceans, such as the Canadian Maritimes could experience such snow squalls.
The areas affected by lake-effect snow are called snowbelts and deposition rate of many inches (centimetres) of snow per hour are common in these situations. In order for lake-effect snow to form, the temperature difference between the water and 850 millibars (850 hPa) should be at least 23 °F (13 °C), surface temperature be around the freezing mark, the lake unfrozen, the path over the lake at least 100 kilometres (62 mi) and the directional wind shear with height should be less than 30° from the surface to 850 millibars (850 hPa).[5] Extremely cold air over still warm water in early winter can even produce thundersnow, snow showers accompanied by lightning and thunder.
Radar trace of lake-effect snow squalls off the Great Lakes from US radars.
Radar image of a strong snow squall off Lake Huron in December 2010. Over 150 cm of snow from this squall, fell north of London, Ontario.[6]
A linear single banded snow squall over Southern Ontario
Frontal snow squall
[edit]
A frontal snow squall is an intense frontal convective line (similar to a squall line), when temperature is near freezing at the surface. The strong convection that develops has enough moisture to produce whiteout conditions at places which line passes over as the wind causes intense blowing snow.[3] This type of snow squall generally lasts less than 30 minutes at any point along its path but the motion of the line can cover large distances. Frontal squalls may form a short distance ahead of the surface cold front or behind the cold front in situations where there are other contributing factors such as dynamic lifting from a deepening low pressure system or a series of trough lines which act similar to a traditional cold frontal passage. In situations where squalls develop post-frontally it is not unusual to have two or three linear squall bands pass in rapid succession only separated by 25 miles (40 km) with each passing the same point in roughly 30 minutes apart.
This is similar to a line of thunderstorms in the summer but the tops of the clouds are only 5,000 to 10,000 feet (1,500 to 3,000 m), often difficult to see on radar. Forecasting these types of events is equivalent to summer severe weather forecast for squall lines: presence of a sharp frontal trough with wind shift and low level jet of more than 30 knots (56 km/h; 35 mph). However, the cold dome behind the trough is at 850 millibars instead of a higher level and must be at least −13 °F (−25 °C). The presence of surface moisture from bodies of water or preexisting liquid precipitation is also a significant contributing factor helping to raise the dew point temperature and saturate the boundary layer. This saturate can significantly increase the amount of convective available potential energy leading to deeper vertical growth and higher precipitable water levels increasing the volume of snow which can be produced by the squall. In cases where there is a large amount of vertical growth and mixing the squall may develop embedded cumulonimbus clouds resulting in lightning and thunder which is dubbed thundersnow.
Dangers
[edit]
Both types of snow squalls are very dangerous for motorists, airplanes, and other travelers; even can be more dangerous than blizzards.[7] The change in conditions is very sudden, with slippery conditions and abrupt loss of visibility due to whiteouts, which often cause multiple-vehicle collisions. In the case of lake-effect snow, heavy amounts of snow can accumulate in short periods of time, possibly causing road closures and paralyzing cities. For instance, on January 9, 2015, a localized, heavy snow squall caused a 193-vehicle pile-up on I-94 highway near Galesburg, Michigan.[8] On very rare occasions, particularly powerful snow squalls can even become supercells and form tornadoes, even if no lightning or thundersnow is present.[9]
See also
[edit]Warnings about lake-effect snow:
- United States
- Lake Effect Snow Advisory
- Lake Effect Snow Warning
- Severe weather terminology (United States)
- Snow squall warning
- Canada
References
[edit]- ^ "National Weather Service Glossary". crh.noaa.gov. Archived from the original on 2006-10-09. Retrieved 2024-03-12.
- ^ B. Geerts (1998). "Lake-Effect Snow". University of Wyoming. Retrieved 2008-12-24.
- ^ a b Meteorological Service of Canada (September 8, 2010). "Snow". Winter Hazards. Environment Canada. Retrieved 2010-10-04.
- ^ Cameron Scott. "What is Lake-Effect Snow". Science 360!. RR Donnelly. Retrieved October 23, 2013.
- ^ Jeff Haby. "Lake-effect forecasting". Haby's Weather Forecasting Hints. theweatherprediction.com. Retrieved 2009-08-12.
- ^ "Snowstorm shuts down London Ontario". CBC News. CBC. December 8, 2010. Retrieved December 13, 2017.
- ^ Allison Chinchar, Meteorologist (18 Dec 2021). "What are snow squalls and why they're more dangerous than blizzards". CNN. Retrieved 19 Feb 2022.
- ^ "Michigan I-94 Pileup | Firefighter Nation". Firefighter Nation. May 2015. Retrieved 2015-10-09.
- ^ Sills, David (2016-11-07). "A Unique Cold-Season Supercell Produces an EF1 'Snownado'". AMS Conference. AMS.
External links
[edit]
Wikimedia Commons has media related to Snowsqualls.
Wikimedia Commons has media related to Snow.
Grokipedia
Snow squall
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Overview
Definition
A snow squall is an intense, short-lived burst of moderate to heavy snowfall accompanied by strong, gusty surface winds and blowing snow, which together cause a sudden onset of whiteout conditions and a rapid drop in visibility to near zero.[6] These events are characterized by their brevity and localization, typically lasting 30 to 60 minutes, though the most intense phase often endures only 5 to 30 minutes.[7] The strong winds, frequently gusting over 35 mph (56 km/h), exacerbate the blowing snow, creating hazardous conditions primarily for motorists due to slick roads and flash freezing.[8] Key criteria distinguishing a snow squall from other winter phenomena include its narrow, linear structure, often forming in bands 1 to 5 miles (1.6 to 8 km) wide, and its lack of sustained duration or widespread impact. Unlike a blizzard, which requires falling or blowing snow reducing visibility to less than 1/4 mile for at least three hours with winds of 35 mph or greater, a snow squall is too brief and confined to meet those thresholds, focusing instead on the abrupt intensity and sudden visibility plunge to under 1/4 mile.[9] Official NWS snow squall warnings, designed as short-fused, polygon-based alerts similar to severe thunderstorm warnings, were piloted in 2018 and implemented nationwide for the 2018-19 winter season to address the unique traffic risks posed by these events.[10] In the 2023-2024 winter season, the NWS enhanced these warnings with impact-based forecasting to better communicate potential dangers like multi-vehicle crashes.[7]Characteristics
Snow squalls can produce intense snowfall rates of 2 to 3 inches (5 to 7.6 cm) per hour or more, though total accumulations are often limited to 1 inch (2.5 cm) or less due to their brevity.[1] The snow particles are typically fine and powdery, owing to low moisture content reflected in high snow-to-liquid ratios ranging from 17:1 to 31:1, which facilitates easy suspension and transport by winds. Recent NWS updates as of the 2024-25 season refined terminology for snow squalls to emphasize their vigorous, short-lived nature in public communications.[11][3] These events are marked by strong, gusty winds with speeds up to 40 to 60 mph (64 to 97 km/h), often accompanied by blowing snow that exacerbates conditions.[12] Visibility can plummet to less than 1/4 mile (400 m) within minutes, creating sudden whiteout scenarios that severely impair travel and observation.[13] Rapid temperature drops are also common, with decreases of 4°F (2.2°C) or more occurring over short periods behind the squall line, and extreme cases showing drops exceeding 20°F (11°C) within an hour during associated cold fronts.[3][14] Occasional thunder, referred to as thundersnow, may accompany snow squalls due to convective instability generating lightning within the heavy snowfall.[15] These phenomena manifest as narrow, fast-moving bands progressing at 25 to 50 mph (40 to 80 km/h), typically spanning 50 to 100 miles in length but only 2 to 20 miles in width.[16] The overall duration remains brief, usually less than 1 hour, with heavy snow phases lasting around 17 minutes on average.[5][](https://www.weather.gov/media/btv/research/S Snow%20Squalls%20Forecasting%20and%20Hazard%20Mitigation.pdf)Formation
Meteorological Conditions
Snow squalls primarily develop during winter along strong cold fronts or within low-pressure systems, where cold Arctic air advects southward over relatively warmer surfaces such as land or unfrozen water bodies. This synoptic setup often features deep-layer cyclonic flow and positioning on the cyclonic shear side of a mid- to upper-tropospheric jet streak, facilitating the advection of cold air masses from polar regions.[3] The incoming air typically exhibits surface temperatures near or below freezing (0°C or 32°F), often dropping further during the event, and 850 hPa temperatures ranging from -12°C to -18°C, promoting conditions suitable for snow formation through dendrite crystal growth.[3] These events are most common in mid-latitude regions, including the Great Lakes area of the United States and Canada, and the Northeast U.S., where an unstable boundary layer develops due to the contrast between the cold air and underlying warmer surfaces. Sufficient low-level moisture is essential, often sourced from nearby large water bodies, frontal boundaries, or residual humidity in the atmosphere, enabling convective initiation.[3][17] In the Northern Hemisphere, snow squalls peak from November to March, with enhanced frequency in areas downwind of large lakes or oceans, where heat and moisture fluxes from the water amplify atmospheric instability. Key instability metrics include low Convective Available Potential Energy (CAPE) values typically ranging from 0 to 100 J/kg, often around 50 J/kg or less in median cases, alongside strong low-level wind shear (median 0–2 km speeds of about 12 m/s) that promotes linear organization of the squalls.[3][17]Physical Mechanisms
Snow squalls arise from mesoscale convective processes where cold air advects over a warmer surface along a cold front, releasing latent heat through condensation and fostering upright convection cells or roll vortices. This convective initiation is driven by surface-based instability, often with low convective available potential energy (CAPE) values below 100 J kg⁻¹, combined with frontogenetic forcing and low-level moisture convergence in the 0–2 km layer above ground level (AGL). The released latent heat enhances upward motion, organizing these cells into linear features that propagate as squall lines, with vertical velocities peaking at 1–2 Pa s⁻¹ in the 950–850 hPa layer.[3][18] Momentum transfer within snow squalls occurs primarily through downdrafts accelerated by evaporative cooling of falling snow, which mixes dry air into the system and intensifies surface gusts. These downdrafts transport higher-momentum air from aloft to the surface, amplified by strong low-level wind shear, such as 30–40 knots at 850 mb perpendicular to the front, sustaining turbulent gustiness and enhancing blowing snow. Steep near-surface lapse rates and isallobaric wind gradients further contribute to this downward momentum flux, resulting in surface winds often exceeding 11 m s⁻¹.[3][19] Snow production in these events stems from moisture convergence in unstable layers, promoting the formation of dendritic ice crystals in a saturated growth zone between -12°C and -18°C, where high snow-to-liquid ratios of 17:1 to 31:1 are common. Buoyancy perturbations drive the vertical motion essential for this process; the buoyancy acceleration, which contributes to vertical velocity $ w $, is given by
where $ g $ is gravitational acceleration, $ \theta $ is the base-state potential temperature, and $ \theta' $ is the perturbation potential temperature. This equation derives from the vertical momentum equation in a Boussinesq approximation, where the buoyancy term $ \frac{g \theta'}{\theta} $ represents the acceleration due to density differences from latent heat release, integrated over depth to yield updrafts that loft moisture for crystal growth.[3][20]
Dissipation of snow squalls happens rapidly, typically within 20–40 minutes, as the system moves downstream and entrains drier air, reducing moisture availability and instability following the frontal passage. The shallow convection weakens above 600 hPa, with vertical motion diminishing and the linear organization breaking apart due to decreasing frontogenetic forcing.[3][18]