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Wikipedia

Lake-effect snow

January 26, 2023

This article is about the weather phenomenon. For other uses, see Lake Effect.

Lake-effect snow is produced during cooler atmospheric conditions when a cold air mass moves across long expanses of warmer lake water. The lower layer of air, heated by the lake water, picks up water vapor from the lake and rises through colder air. The vapor then freezes and is deposited on the leeward (downwind) shores.[1]

A cold northwesterly to westerly wind over all the Great Lakes created the lake-effect snowfall of January 10, 2022.

The same effect also occurs over bodies of saline water, when it is termed ocean-effect or bay-effect snow. The effect is enhanced when the moving air mass is uplifted by the orographic influence of higher elevations on the downwind shores. This uplifting can produce narrow but very intense bands of precipitation, which deposit at a rate of many inches of snow each hour, often resulting in a large amount of total snowfall.

The areas affected by lake-effect snow are called snowbelts. These include areas east of the Great Lakes in North America, the west coasts of northern Japan, the Kamchatka Peninsula in Russia, and areas near the Great Salt Lake, Black Sea, Caspian Sea, Baltic Sea, Adriatic Sea, and North Sea.

Lake-effect blizzards are the blizzard-like conditions resulting from lake-effect snow. Under certain conditions, strong winds can accompany lake-effect snows creating blizzard-like conditions; however, the duration of the event is often slightly less than that required for a blizzard warning in both the US and Canada.[2]

If the air temperature is low enough to keep the precipitation frozen, it falls as lake-effect snow. If not, then it falls as lake-effect rain. For lake-effect rain or snow to form, the air moving across the lake must be significantly cooler than the surface air (which is likely to be near the temperature of the water surface). Specifically, the air temperature at an altitude where the air pressure is 850 millibars (85 kPa) (roughly 1.5 kilometers or 5,000 feet vertically) should be 13 °C (23 °F) lower than the temperature of the air at the surface. Lake-effect occurring when the air at 850 millibars (85 kPa) is much colder than the water surface can produce thundersnow, snow showers accompanied by lightning and thunder (caused by larger amounts of energy available from the increased instability).

Formation

 
Lake-effect snow is produced as cold winds blow clouds over warm waters.

Some key elements are required to form lake-effect precipitation and which determine its characteristics: instability, fetch, wind shear, upstream moisture, upwind lakes, synoptic (large)-scale forcing, orography/topography, and snow or ice cover.

Instability

A temperature difference of 13 °C (23 °F) (or as past researchers have estimated: between 15 and 25 °C) between the lake temperature and the height in the atmosphere (about 1,500 m or 5,000 ft at which barometric pressure measures 850 mbar or 85 kPa) provides for absolute instability and allows vigorous heat and moisture transportation vertically. Atmospheric lapse rate and convective depth are directly affected by both the mesoscale lake environment and the synoptic environment; a deeper convective depth with increasingly steep lapse rates and a suitable moisture level allow for thicker, taller lake-effect precipitation clouds and naturally a much greater precipitation rate.[3]

Fetch

The distance that an air mass travels over a body of water is called fetch. Because most lakes are irregular in shape, different angular degrees of travel yield different distances; typically, a fetch of at least 100 km (60 mi) is required to produce lake-effect precipitation. Generally, the larger the fetch, the more precipitation produced. Larger fetches provide the boundary layer with more time to become saturated with water vapor and for heat energy to move from the water to the air. As the air mass reaches the other side of the lake, the engine of rising and cooling water vapor pans itself out in the form of condensation and falls as snow, usually within 40 km (25 mi) of the lake, but sometimes up to about 150 km (100 mi).[4]

 
The location of common lake-effect bands on the Great Lakes

Wind shear

Directional shear is one of the most important factors governing the development of squalls; environments with weak directional shear typically produce more intense squalls than those with higher shear levels. If directional shear between the surface and the height in the atmosphere at which the barometric pressure measures 700 mb (70 kPa) is greater than 60°, nothing more than flurries can be expected. If the directional shear between the body of water and the vertical height at which the pressure measures 700 mb (70 kPa) is between 30° and 60°, weak lake-effect bands are possible. In environments where the shear is less than 30°, strong, well organized bands can be expected.[5]

Speed shear is less critical but should be relatively uniform. The wind-speed difference between the surface and vertical height at which the pressure reads 700 mb (70 kPa) should be no greater than 40 knots (74 km/h) so as to prevent the upper portions of the band from shearing off. However, assuming the surface to 700 mb (70 kPa) winds are uniform, a faster overall velocity works to transport moisture more quickly from the water, and the band then travels much farther inland.[5]

 
Temperature difference and instability are directly related, the greater the difference, the more unstable and convective the lake-effect precipitation will be.

Upstream moisture

A lower upstream relative humidity lake effect makes condensation, clouds, and precipitation more difficult to form. The opposite is true if the upstream moisture has a high relative humidity, allowing lake-effect condensation, cloud, and precipitation to form more readily and in a greater quantity.[6]

Upwind lakes

Any large body of water upwind impacts lake-effect precipitation to the lee of a downwind lake by adding moisture or pre-existing lake-effect bands, which can reintensify over the downwind lake. Upwind lakes do not always lead to an increase of precipitation downwind.[7]

Synoptic forcing

Vorticity advection aloft and large upscale ascent help increase mixing and the convective depth, while cold air advection lowers the temperature and increases instability.[8]

Orography and topography

Typically, lake-effect precipitation increases with elevation to the lee of the lake as topographic forcing squeezes out precipitation and dries out the squall much faster.[9]

Snow and ice cover

As a lake gradually freezes over, its ability to produce lake-effect precipitation decreases for two reasons. Firstly, the open ice-free liquid surface area of the lake shrinks. This reduces fetch distances. Secondly, the water temperature nears freezing, reducing overall latent heat energy available to produce squalls. To end the production of lake-effect precipitation, a complete freeze is often not necessary.[10]

Even when precipitation is not produced, cold air passing over warmer water may produce cloud cover. Fast-moving mid-latitude cyclones, known as Alberta clippers, often cross the Great Lakes. After the passage of a cold front, winds tend to switch to the northwest, and a frequent pattern is for a long-lasting low-pressure area to form over the Canadian Maritimes, which may pull cold northwestern air across the Great Lakes for a week or more, commonly identified with the negative phase of the North Atlantic Oscillation (NAO). Since the prevailing winter winds tend to be colder than the water for much of the winter, the southeastern shores of the lakes are almost constantly overcast, leading to the use of the term "the Great Gray Funk" as a synonym for winter.[citation needed] These areas allegedly contain populations that suffer from high rates of seasonal affective disorder, a type of psychological depression thought to be caused by lack of light.[11][citation needed]

Great Lakes region

United States

 
Lake effect snow bands over Central New York
 
Map showing some of the lake-effect snow areas of the United States

Cold winds in the winter typically prevail from the northwest in the Great Lakes region, producing the most dramatic lake-effect snowfalls on the southern and eastern shores of the Great Lakes. This lake effect results in much greater snowfall amounts on the southern and eastern shores compared to the northern and western shores of the Great Lakes.

The most affected areas include the Upper Peninsula of Michigan; Central New York; Western New York; Northwestern Pennsylvania; Northeastern Ohio; southwestern Ontario and central Ontario; Northeastern Illinois (along the shoreline of Lake Michigan); northwestern and north central Indiana (mostly between Gary and Elkhart); northern Wisconsin (near Lake Superior); and West Michigan. Tug Hill in New York's North Country region has the second-most snow amounts of any nonmountainous location within the continental U.S., trailing only the Upper Peninsula, which can average over 200 in (508 cm) of snow per year.[12]

Lake-effect snows on the Tug Hill plateau (east of Lake Ontario) can frequently set daily records for snowfall in the United States. Tug Hill receives, typically, over 20 feet (240 in; 610 cm) of snow each winter.[13] In February 2007, a prolonged lake-effect snow event left 141 inches (358 cm) of snow on the Tug Hill Plateau.[14] Syracuse, New York, directly south of the Tug Hill Plateau, receives significant lake-effect snow from Lake Ontario, and averages 115.6 inches (294 cm) of snow per year, which is enough snowfall to be considered one of the "snowiest" large cities in America.[15][16]

A small amount of lake-effect snow from the Finger Lakes falls in upstate New York, as well. If the wind blows almost the entire length of either Cayuga Lake or Seneca Lake, Ithaca or Watkins Glen, respectively, can have a small lake-effect snowstorm.

Lake Erie produces a similar effect for a zone stretching from the eastern suburbs of Cleveland through Erie to Buffalo.[17] Remnants of lake-effect snows from Lake Erie have been observed to reach as far south as Garrett County, Maryland, and as far east as Geneva, New York.[18] Because it is not as deep as the other lakes, Erie warms rapidly in the spring and summer, and is frequently the only Great Lake to freeze over in winter.[19] Once frozen, the resulting ice cover alleviates lake-effect snow downwind of the lake. Based on stable isotope evidence from lake sediment coupled with historical records of increasing lake-effect snow, global warming has been predicted to result in a further increase in lake-effect snow.[20]

A very large snowbelt in the United States exists on the Upper Peninsula of Michigan, near the cities of Houghton, Marquette, and Munising. These areas typically receive 250–300 inches (635–762 cm) of snow each season.[21] For comparison, on the western shore, Duluth, Minnesota receives 78 inches (198 cm) per season.[22] Lake Superior and Lake Huron rarely freeze because of their size and depth; hence, lake-effect snow can fall continually in the Upper Peninsula and Canadian snowbelts during the winter. Main areas of the Upper Peninsula snow belt include the Keweenaw Peninsula and Baraga, Marquette and Alger Counties, where Lake Superior contributes to lake-effect snow, making them a prominent part of the Midwestern snow belt. Records of 390 inches (991 cm) of snow or more have been set in many communities in this area. The Keweenaw Peninsula averages more snowfall than almost anywhere in the United States—more than anywhere east of the Mississippi River and most of all nonmountainous regions of the continental United States. Because of the howling storms across Lake Superior, which cause dramatic amounts of precipitation, the lake-effect snow is said to make the Keweenaw Peninsula the snowiest place east of the Rockies. Only one official weather station exists in this region. Located in Hancock, Michigan; this station averages well over 210 inches (533 cm) per year. Farther north in the peninsula, lake-effect snow can occur with any wind direction. The road commission in Keweenaw County, Michigan, collects unofficial data in a community called Delaware, and it strictly follows the guidelines set forth by the National Weather Service. This station averages over 240 inches (610 cm) per season. Even farther north, a ski resort called Mount Bohemia receives an unofficial annual average of 273 inches (693 cm). Herman, Michigan, averages 236 inches (599 cm) of snow every year. Lake-effect snow can cause blinding whiteouts in just minutes, and some storms can last days.

Western Michigan, western Northern Lower Michigan, and Northern Indiana can get heavy lake-effect snows as winds pass over Lake Michigan and deposit snows over Muskegon, Traverse City, Grand Rapids, Kalamazoo, New Carlisle, South Bend, and Elkhart, but these snows abate significantly before Lansing or Fort Wayne, Indiana. When winds become northerly or aligned between 330 and 390°, a single band of lake-effect snow may form, which extends down the length of Lake Michigan. This long fetch often produces a very intense, yet localized, area of heavy snowfall, affecting cities such as La Porte and Gary.[23]

Lake-effect snow is uncommon in Detroit, Toledo, Milwaukee, and Chicago, because the region's dominant winds are from the northwest, making them upwind from their respective Great Lakes, although they, too, can see lake-effect snow during easterly or northeasterly winds. More frequently, the north side of a low-pressure system picks up more moisture over the lake as it travels east, creating a phenomenon called lake-enhanced precipitation.[23]

  •  

    Buffalo, New York, after 82.3 inches (209 cm) of snow fell from December 24, 2001, to December 28, 2001

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    Fulton, New York, after a snowburst dropped 4–6 feet (122–183 cm) of snow over most of Oswego County January 28–31, 2004

  •  

    The Veteran's Day storm of November 9–14, 1996, may be the most severe early-season lake-effect snow storm the Great Lakes has witnessed in the past 50 years. At the height of the storm, over 160,000 customers were without power in Greater Cleveland alone, as the storm produced isolated snowfall tallies approaching 70 inches (178 cm).

Ontario, Canada

 
Visible satellite image showing a large single lake-effect band from Lake Huron with vigorous vertical motion: This band produced 8 inches (20 cm) of snow in the eastern and northern suburbs of Toronto, Ontario.
 
The community of Wasaga Beach after 60 cm (24 in) of snow fell in 12 hours from a persistent lake-effect band

Because Southwestern Ontario is surrounded by water on three sides, many parts of Southwestern and Central Ontario get a large part of their winter snow from lake-effect snow.[24] This region is notorious for the whiteouts that can suddenly reduce highway visibility on North America’s busiest highway (Ontario Highway 401)[25] from clear to zero. The region most commonly affected spans from Port Stanley in the west, the Bruce Peninsula in the north, Niagara-on-the-Lake to the east, and Fort Erie to the south. The heaviest accumulations usually happen in the Bruce Peninsula, which is between Lake Huron and Georgian Bay. So long as the Great Lakes are not frozen over, the only time the Bruce Peninsula does not get lake-effect snow is when the wind is directly from the south.

Toronto and Hamilton are usually spared lake-effect squalls because they are not on the leeward side of Lake Ontario during the dominant northwest winds. Some central and northern portions of the Greater Toronto Area, though, can be affected a few times each year by lake-effect snow from Georgian Bay. Downtown Toronto and Hamilton get most of their lake-effect snow when the wind comes from the southeast or east, over Lake Ontario. Such easterly winds are usually associated with a winter cyclone passing just to the south of the Great Lakes.

When the wind is from the north, the snowbelt runs north-south from Grand Bend to Sarnia and London. Areas such as Lucan and Kincardine have experienced some of the heaviest snowsqualls from Lake Huron in this region. When the wind is slightly more westerly, the snowbelt runs from Tobermory, Owen Sound, and Grand Bend to as far south and east as Arthur, Orangeville and Caledon. This snowbelt often reaches Kitchener and can affect the Halton and Peel regions of the Greater Toronto Area. These northwesterly winds usually also bring snow southeast of Georgian Bay, which can reach beyond Lake Scugog. A westerly wind sends lake-effect streamers east from Owen Sound to Gravenhurst, Barrie, and Orillia, and may even reach as far south and east as York Region in the Greater Toronto Area. When the wind is from the southwest, lake-effect streamers from Lake Huron and Georgian Bay run from Noelville to Sudbury, Gravenhurst, and Algonquin Provincial Park. Winds from this same direction coming over Lake Ontario cause squalls to come ashore from Cobourg through the Belleville area to Kingston and the Thousand Islands, with Prince Edward County being the area most vulnerable to extreme snowfall amounts. Some snow bands can occasionally reach Quebec and Maine, while snow originating from Lake Erie, Lake Ontario, and even Lake Michigan can impact southern Ontario. Easterly winds primarily affect the Niagara Peninsula. Local lake-effect snowsqualls can occasionally occur downwind of Lake Simcoe when the lake is unfrozen, usually in early winter or late fall.

Lake Superior has its own independent snowbelts, affecting Wawa, Sault Ste. Marie, Marathon, the Keweenaw Peninsula in Upper Michigan, and Pukaskwa National Park. Thunder Bay is usually not affected by lake-effect snow, unless it is associated with a winter storm.

Elsewhere in the United States

See also: Great Salt Lake effect

The southern and southeastern sides of the Great Salt Lake receive significant lake-effect snow. Since the Great Salt Lake never freezes, the lake effect can influence the weather along the Wasatch Front year-round. The lake effect largely contributes to the 55–80 inches (140–203 cm) annual snowfall amounts recorded south and east of the lake, and in average snowfall reaching 500 inches (13 m) in the Wasatch Range. The snow, which is often very light and dry because of the semiarid climate, is referred to as the "Greatest Snow on Earth" in the mountains. Lake-effect snow contributes to roughly six to eight snowfalls per year in Salt Lake City, with about 10% of the city's precipitation being contributed by the phenomenon.[26]

Similar snowfall can occur near large inland bays, where it is known as bay-effect snow. Bay-effect snows fall downwind of Delaware Bay, Chesapeake Bay, and Massachusetts Bay when the basic criteria are met, and on rarer occasions along Long Island.

The Finger Lakes of New York are long enough for lake-effect precipitation.

The Texas twin cities of Sherman and Denison are known, in rare instances, to have experienced lake-effect snow from nearby Lake Texoma due to the lake's size (it is the third-largest lake in Texas or along its borders).

On one occasion in December 2016, lake-effect snow fell in central Mississippi from a lake band off Ross Barnett Reservoir.[27]

Oklahoma City even had a band of lake-effect snow off of Lake Hefner in February 2018.

Owasso/Collinsville, Oklahoma outside of Tulsa, had lake effect snow off Lake Oolagah during a winter storm in February 2021.

The Truckee Meadows and other parts of northern Nevada, which are normally in the rain shadow of the Sierra Nevada, when conditions are right, can have severe snowfall as a result of lake effect from Lake Tahoe. Recent severe examples of this phenomenon have occurred as recently as 2004, dumping several feet of snow in the normally dry region.

The West Coast occasionally experiences ocean-effect showers, usually in the form of rain at lower elevations south of about the mouth of the Columbia River. These occur whenever an Arctic air mass from western Canada is drawn westward out over the Pacific Ocean, typically by way of the Fraser Valley, returning shoreward around a center of low pressure. Cold air flowing southwest from the Fraser Valley can also pick up moisture over the Strait of Georgia and Strait of Juan de Fuca, then rise over the northeastern slopes of the Olympic Mountains, producing heavy, localized snow between Port Angeles and Sequim, as well as areas in Kitsap County and the Puget Sound region.[28]

While snow of any type is very rare in Florida, the phenomenon of gulf-effect snow has been observed along the northern coast of the Gulf of Mexico a few times in history. More recently, "ocean-effect" snow occurred on January 24, 2003, when wind off the Atlantic, combined with air temperatures in the 30 °F range, brought snow flurries briefly to the Atlantic Coast of northern Florida seen in the air as far south as Cape Canaveral.[29]

Elsewhere in Canada

Lake Winnipeg, Lake Manitoba and Lake Winnipegosis in Manitoba historically have seen lake-effect snow as early as late October, and it is common throughout early to mid-November. Towards the end of November, the lakes sufficiently cool and begin to freeze, ending the lake-effect snow. A brief period of lake-effect snow is also common near Great Bear Lake and Great Slave Lake in the Northwest Territories during early winter (usually early to mid-October); the lake-effect season for both lakes is very short, though. The lakes are frozen roughly eight months of the year, and as a result, have very little time to warm during the summer.

Other small lakes such as Lake Athabasca in northern Saskatchewan and Lake Nipigon in northwestern Ontario produce early-season lake-effect snows. Smallwood Reservoir, a man-made lake located in Labrador, has on occasion generated lake-effect snow.

The Canadian Maritimes, specifically Nova Scotia and Prince Edward Island, are often affected by such snow squalls when an Arctic winter airmass moves over unfrozen waters. In PEI, sea-effect snow is often generated when a cold north wind blows over the unfrozen Gulf of St. Lawrence, dumping heavy snow on the north shore. In Nova Scotia, a cold north-west wind can produce sea-effect snow over the Cape Breton Highlands from the Gulf of St. Lawrence, and the Annapolis Valley from the Bay of Fundy; in the latter case, the sea-effect snow season can continue all winter as the Bay of Fundy remains open owing to its extreme tidal currents.

The east coast of southern Vancouver Island, British Columbia, experiences occasional episodes of sea-effect snow during winter due to cold easterly outflow winds from the British Columbia interior, typically through the Fraser Valley, crossing the always open waters of the Strait of Georgia.

Eurasia

Lake-effect or sea-effect snow occurs in other countries, near large lakes or large sea areas. In Eurasia, it occurs in the regions of the Black Sea in Georgia, Romania, Bulgaria and northern Turkey, the Caspian Sea in Iran, the Adriatic Sea in Italy, the North Sea, the Irish Sea, the Aegean Sea, the Balearic Islands, and the Baltic Sea, as well as areas surrounding the Sea of Japan.

Because the southern Black Sea is relatively warm (around 13 °C or 55 °F at the beginning of winter, typically 10 to 6 °C or 50 to 43 °F by the end), sufficiently cold air aloft can create significant snowfalls in a relatively short period of time. Due to its location on a peninsula between the Black Sea and the Sea of Marmara, Istanbul is very prone to lake-effect snow and this weather phenomenon occurs almost every winter. This type of precipitation is generated by the warmer Black Sea temperature and colder air temperature, over the Istanbul area. In February 2005, a lake-effect snowfall left 50 cm (20 in) of snow, and in March 1987, a three-week-long lake-effect snowfall accompanied with strong winds (lake-effect blizzard) left 80 cm (31 in) of snow in Istanbul.[30] The snowfall in the eastern regions of the Black Sea is amplified by the orographic effect of the nearby Caucasus Mountains, often resulting in snowfall of several meters, especially at higher elevations.

In the Adriatic regions of Italy and in the eastern Apennine Mountains, the sea-effect snow phenomenon with air masses coming from Northern or Eastern Europe (and Russia) can be incredibly heavy and can last for days. In the hills and mountains, it can result in snowfalls of several meters, as it happened in February 2012. These huge amounts of snow can also fall in short periods of time.

In Northern Europe, cold, dry air masses from Russia can blow over the Baltic Sea and cause heavy snow squalls on areas of the southern and eastern coasts of Sweden, as well as on the Danish island of Bornholm, the east coast of Jutland and the northern coast of Poland. For the northern parts of the Baltic Sea, this happens mainly in the early winter, since it freezes later. Southeast Norway can also experience heavy sea snow events with east-north-easterly winds. Especially, coastal areas from Kragero to Kristiansand have had incredible snow depths in the past with intense persistent snowbands from Norwegian Sea (the coastal city of Arendal recorded 280 cm (110 in) in a single week in late February 2007).[31] Although Fennoscandia is lined with an abundance of lakes, this type of snowfall is rare in these, due to the shallow freshwater freezing early in the cold interiors. One notable exception happened in the middle of May 2008, as Leksand on the since-long unfrozen lake of Siljan got 30 cm (12 in) on the ground.[32]

The Sea of Japan creates snowfall in the mountainous western Japanese prefectures of Niigata and Nagano, parts of which are known collectively as snow country (Yukiguni). In addition to the Sea of Japan, other parts of Japan, as well as Korea and Shandong Peninsula,[33] experience these same conditions.

Because the Aegean Sea (Greece), is warm in the winter, when cold air masses from Siberia advance in the area, they pick up much moisture, resulting in heavy snowfalls in eastern Central Greece, eastern Thessaly, eastern Peloponnese, south-eastern Chalkidiki, the Cyclades, and Crete (more commonly in the mountainous areas). In 2008, a severe snowstorm blanketed Athens, dropping 40 cm (16 in) of snow and causing huge traffic jams.

Moving of polar or Siberian high-pressure centers along Caspian Sea regarding to relatively warmer water of this sea can make heavy snowfalls in the northern coast of Iran. Several blizzards have been reported in this region during the last decades. In February 2014, heavy snowfall reached 200 cm (79 in) on the coastline in Gilan and Mazandaran provinces of Iran. The heaviest snowfall was reported in Abkenar village near Anzali Lagoon.[34][35][36][37]

  •  

    IRIMO[38] radar animation of lake effect snow in southern coast of Caspian Sea in the north of Iran

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    Lake-effect clouds over Caspian Sea on January 7, 2008

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    Lake effect snow in Athens on February 16, 2021

  •  

    Lake effect snow in Athens on February 16, 2021

United Kingdom

In the United Kingdom, easterly winds bringing cold continental air across the North Sea can lead to a similar phenomenon. Locally, it is also known as "lake-effect snow" despite the snow coming in from the sea rather than a lake.[39] Similarly during a north-westerly wind, snow showers can form coming in from the Liverpool Bay, coming down the Cheshire gap, causing snowfall in the West Midlands—this formation resulted in the white Christmas of 2004 in the area, and most recently the heavy snowfall of 8 December 2017 and 30 January 2019.[40][41] A similar phenomenon can affect the city of Inverness in the Scottish Highlands, where cold north-east winds cause heavy snow to form in the Moray Firth; this was the case with the White Hogmanay of 2009, which caused the street party to be cancelled. Northerly and north-westerly winds can cause the effect to occur over the Irish Sea and Bristol Channel feeding snow into South West England and eastern Ireland. Western Scotland and northern Ireland can also see snow showers from a north or north-westerly wind over the Atlantic.

Since the North Sea is relatively warm (around 13 °C or 55.4 °F at the beginning of winter, typically 10 to 6 °C or 50 to 43 °F by the end), sufficiently cold air aloft can create significant snowfalls in a relatively short period of time. The best-known example occurred in January 1987, when record-breaking cold air (associated with an upper low) moved across the North Sea towards the UK. The end result was over 2 ft of snow for coastal areas, leading to communities being cut off for over a week. The latest of these events to affect Britain's east coast occurred on November 30, 2017; February 28, 2018; and March 17, 2018; in connection with the 2018 Great Britain and Ireland cold wave.[42] The second event of winter 2017/18 was particularly severe, with up to 27.5 inches (70 cm) falling in total over the 27th–28th.[43]

Similarly, northerly winds blowing across the relatively warm waters of the English Channel during cold spells can bring significant snowfall to the French region of Normandy, where snow drifts exceeding 10 ft (3 m) were measured in March 2013.[44]

  •  

    Chart showing the sea-effect snow event of January 1987 in the UK: A continuous stream of showers deposited over 2 feet (24 in) of snow over SE coastal regions.

  •  

    NetWeather[45] radar image showing "lake-effect" snow over Kent and northeast England

See also

Warnings about lake-effect snow:

United States:
Canada:

References

  1. ^ . National Oceanic and Atmospheric Administration. Archived from the original on January 2, 2015. Retrieved January 2, 2015.
  2. ^ "WFO Winter Weather Products Specification" (PDF). National Weather Service. May 7, 2020. (PDF) from the original on August 18, 2006.
  3. ^ Byrd, Greg (June 3, 1998). . University Corporation for Atmospheric Research. Archived from the original on June 17, 2009.
  4. ^ Byrd, Greg (June 3, 1998). . University Corporation for Atmospheric Research. Archived from the original on May 15, 2008.
  5. ^ a b Byrd, Greg (June 3, 1998). . University Corporation for Atmospheric Research. Archived from the original on May 11, 2008.
  6. ^ Byrd, Greg (June 3, 1998). . University Corporation for Atmospheric Research. Archived from the original on May 9, 2008.
  7. ^ Byrd, Greg (June 3, 1998). . University Corporation for Atmospheric Research. Archived from the original on May 9, 2008.
  8. ^ Byrd, Greg (June 3, 1998). . University Corporation for Atmospheric Research. Archived from the original on May 16, 2008.
  9. ^ Byrd, Greg (June 3, 1998). . University Corporation for Atmospheric Research. Archived from the original on May 9, 2008.
  10. ^ Byrd, Greg (June 3, 1998). . University Corporation for Atmospheric Research. Archived from the original on May 15, 2008.
  11. ^ . The Weather Underground. Archived from the original on February 21, 2007. Retrieved January 4, 2007.
  12. ^ . The Climate Source. 2003. Archived from the original on June 9, 2008.
  13. ^ . Northern Forest Alliance. Archived from the original on May 9, 2008. Retrieved February 1, 2015.
  14. ^ . National Climatic Data Center. March 15, 2007. Archived from the original on December 21, 2007. Retrieved March 1, 2008.
  15. ^ Cappella, Chris (October 3, 2003). . USA Today. Archived from the original on October 12, 2011.
  16. ^ Kirst, Sean (March 14, 2005). "We won't buckle under the Snowbelt's blows". The Post-Standard.
  17. ^ Schmidlin, Thomas W. (1989). "Climatic Summary of Snowfall and Snow Depth in the Ohio Snowbelt at Chardon" (PDF). The Ohio Journal of Science. 89 (4): 101–108. (PDF) from the original on July 16, 2007. Retrieved March 1, 2008.
  18. ^ . Northeast Regional Climate Center. February 1995. Archived from the original on June 11, 2007. Retrieved March 1, 2008.
  19. ^ . Great Lakes Information Network. Archived from the original on May 9, 2008. Retrieved March 1, 2008.
  20. ^ Burnett, Adam W.; Kirby, Matthew E.; Mullins, Henry T.; Patterson, William P. (2003). "Increasing Great Lake–Effect Snowfall during the Twentieth Century: A Regional Response to Global Warming?". Journal of Climate. 16 (21): 3535–3542. Bibcode:2003JCli...16.3535B. doi:10.1175/1520-0442(2003)016<3535:IGLSDT>2.0.CO;2. S2CID 58935593.
  21. ^ Ruhf, Robert J. "Lake-Effect Precipitation in Michigan". Dr. Robert J. Ruhf. Retrieved March 1, 2008.
  22. ^ . University of Utah, Department of Meteorology. Archived from the original on February 12, 2008. Retrieved March 1, 2008.
  23. ^ a b . Great Lakes Integrated Sciences and Assessments. Archived from the original on April 13, 2014. Retrieved April 10, 2014.
  24. ^ Scott, Cameron (December 14, 2010). "How Lakes Affect Snowfalls". Sciences360.com.
  25. ^ Jennings, Ken (June 18, 2018). "The World's Widest Highway Spans a Whopping 26 Lanes". Condé Nast Traveler. Retrieved February 17, 2021.
  26. ^ Bauman, Joe (August 5, 1999). . Deseret News. Archived from the original on October 2, 2012.
  27. ^ Hutton, Brian (December 20, 2016). "Tuesday, December 20 Afternoon Forecast Discussion". WTOK-TV.
  28. ^ Mass, Cliff (2008). The Weather of the Pacific Northwest. University of Washington Press. p. 60. ISBN 978-0-295-98847-4.
  29. ^ "Cold Temperatures and Snow Flurries in East-Central Florida January 24, 2003" (PDF). National Weather Service Office, Melbourne, Florida. (PDF) from the original on January 27, 2017. Retrieved November 5, 2006.
  30. ^ Kindap, T. & Gokturk, O. M. (2006). "The Black Sea impact on the severe snow episode over the city of Istanbul" (PDF). Geophysical Research Abstracts. 8. (PDF) from the original on July 29, 2014.
  31. ^ [Report on weather and driving conditions in Agder in the period 20-28 February 2007]. Statens vegvesen [State Highways Authority] (in Norwegian). May 1, 2007. Archived from the original on October 25, 2019. Retrieved October 25, 2019.
  32. ^ "Maj 2008 - Både sommarvärme och sent snöfall" (in Swedish). Swedish Meteorological and Hydrological Institute. June 2, 2008. Retrieved March 31, 2022.
  33. ^ Bao, Baoleerqimuge & Ren, Guoyu (May 2018). "Sea-Effect Precipitation over the Shandong Peninsula, Northern China". Journal of Applied Meteorology and Climatology. 57 (6): 1291–1308. Bibcode:2018JApMC..57.1291B. doi:10.1175/JAMC-D-17-0200.1. S2CID 126039299.
  34. ^ "Snow Blankets Iran". NASA Earth Observatory. February 11, 2014.
  35. ^ "Iran snow cuts power to nearly 500,000 homes". BBC News. February 3, 2014.
  36. ^ . National Geographic. January 10, 2008. Archived from the original on July 24, 2008.
  37. ^ . The Observers. France 24. February 14, 2014. Archived from the original on February 22, 2014. Retrieved February 14, 2014.
  38. ^ (in Persian). Iran Meteorological Organization. Archived from the original on August 29, 2014. Retrieved January 1, 2022.
  39. ^ "Conversations". uk.sci.weather archives. Retrieved August 3, 2007.
  40. ^ "Snow closes schools in Greater Manchester plus city airports". BBC News. January 30, 2019.
  41. ^ Rowden, Nathan (December 8, 2017). "Heavy snow causes chaos in Shropshire - and there's more on the way". Shropshire Star.
  42. ^ "Snow falls on England's east coast beaches". BBC News. November 30, 2017.
  43. ^ Hopewell, John (February 28, 2018). "Brutal storm is pummeling Britain with heavy snow and wicked wind chill". The Washington Post.
  44. ^ [Snow. The month of March of all records in Normandy]. actu.fr (in French). March 14, 2013. Archived from the original on December 3, 2013. Retrieved November 26, 2013.
  45. ^ "Netweather". netweather.tv.

External links

 
Wikimedia Commons has media related to Lake effect snow.
  • National Weather Service Official Lake Effect Page—based in Buffalo, NY
  • Lake effect forecasting
  • Video of a snowsquall timelapse while driving on Highway 407 ETR in Greater Toronto
  • Digital Snow Museum
  • Ice and snow measurements on lakes and surrounding land areas 2010-05-27 at the Wayback Machine, Great Lakes Environmental Research Laboratory
  • A BBC forecast of lake effect snow in the UK in 1991

January 26, 2023
lake, effect, snow, this, article, about, weather, phenomenon, other, uses, lake, effect, produced, during, cooler, atmospheric, conditions, when, cold, mass, moves, across, long, expanses, warmer, lake, water, lower, layer, heated, lake, water, picks, water, . This article is about the weather phenomenon For other uses see Lake Effect Lake effect snow is produced during cooler atmospheric conditions when a cold air mass moves across long expanses of warmer lake water The lower layer of air heated by the lake water picks up water vapor from the lake and rises through colder air The vapor then freezes and is deposited on the leeward downwind shores 1 A cold northwesterly to westerly wind over all the Great Lakes created the lake effect snowfall of January 10 2022 The same effect also occurs over bodies of saline water when it is termed ocean effect or bay effect snow The effect is enhanced when the moving air mass is uplifted by the orographic influence of higher elevations on the downwind shores This uplifting can produce narrow but very intense bands of precipitation which deposit at a rate of many inches of snow each hour often resulting in a large amount of total snowfall The areas affected by lake effect snow are called snowbelts These include areas east of the Great Lakes in North America the west coasts of northern Japan the Kamchatka Peninsula in Russia and areas near the Great Salt Lake Black Sea Caspian Sea Baltic Sea Adriatic Sea and North Sea Lake effect blizzards are the blizzard like conditions resulting from lake effect snow Under certain conditions strong winds can accompany lake effect snows creating blizzard like conditions however the duration of the event is often slightly less than that required for a blizzard warning in both the US and Canada 2 If the air temperature is low enough to keep the precipitation frozen it falls as lake effect snow If not then it falls as lake effect rain For lake effect rain or snow to form the air moving across the lake must be significantly cooler than the surface air which is likely to be near the temperature of the water surface Specifically the air temperature at an altitude where the air pressure is 850 millibars 85 kPa roughly 1 5 kilometers or 5 000 feet vertically should be 13 C 23 F lower than the temperature of the air at the surface Lake effect occurring when the air at 850 millibars 85 kPa is much colder than the water surface can produce thundersnow snow showers accompanied by lightning and thunder caused by larger amounts of energy available from the increased instability Contents 1 Formation 1 1 Instability 1 2 Fetch 1 3 Wind shear 1 4 Upstream moisture 1 5 Upwind lakes 1 6 Synoptic forcing 1 7 Orography and topography 1 8 Snow and ice cover 2 Great Lakes region 2 1 United States 2 2 Ontario Canada 3 Elsewhere in the United States 4 Elsewhere in Canada 5 Eurasia 6 United Kingdom 7 See also 8 References 9 External linksFormation Edit Lake effect snow is produced as cold winds blow clouds over warm waters Some key elements are required to form lake effect precipitation and which determine its characteristics instability fetch wind shear upstream moisture upwind lakes synoptic large scale forcing orography topography and snow or ice cover Instability Edit A temperature difference of 13 C 23 F or as past researchers have estimated between 15 and 25 C between the lake temperature and the height in the atmosphere about 1 500 m or 5 000 ft at which barometric pressure measures 850 mbar or 85 kPa provides for absolute instability and allows vigorous heat and moisture transportation vertically Atmospheric lapse rate and convective depth are directly affected by both the mesoscale lake environment and the synoptic environment a deeper convective depth with increasingly steep lapse rates and a suitable moisture level allow for thicker taller lake effect precipitation clouds and naturally a much greater precipitation rate 3 Fetch Edit The distance that an air mass travels over a body of water is called fetch Because most lakes are irregular in shape different angular degrees of travel yield different distances typically a fetch of at least 100 km 60 mi is required to produce lake effect precipitation Generally the larger the fetch the more precipitation produced Larger fetches provide the boundary layer with more time to become saturated with water vapor and for heat energy to move from the water to the air As the air mass reaches the other side of the lake the engine of rising and cooling water vapor pans itself out in the form of condensation and falls as snow usually within 40 km 25 mi of the lake but sometimes up to about 150 km 100 mi 4 The location of common lake effect bands on the Great Lakes Wind shear Edit Directional shear is one of the most important factors governing the development of squalls environments with weak directional shear typically produce more intense squalls than those with higher shear levels If directional shear between the surface and the height in the atmosphere at which the barometric pressure measures 700 mb 70 kPa is greater than 60 nothing more than flurries can be expected If the directional shear between the body of water and the vertical height at which the pressure measures 700 mb 70 kPa is between 30 and 60 weak lake effect bands are possible In environments where the shear is less than 30 strong well organized bands can be expected 5 Speed shear is less critical but should be relatively uniform The wind speed difference between the surface and vertical height at which the pressure reads 700 mb 70 kPa should be no greater than 40 knots 74 km h so as to prevent the upper portions of the band from shearing off However assuming the surface to 700 mb 70 kPa winds are uniform a faster overall velocity works to transport moisture more quickly from the water and the band then travels much farther inland 5 Temperature difference and instability are directly related the greater the difference the more unstable and convective the lake effect precipitation will be Upstream moisture Edit A lower upstream relative humidity lake effect makes condensation clouds and precipitation more difficult to form The opposite is true if the upstream moisture has a high relative humidity allowing lake effect condensation cloud and precipitation to form more readily and in a greater quantity 6 Upwind lakes Edit Any large body of water upwind impacts lake effect precipitation to the lee of a downwind lake by adding moisture or pre existing lake effect bands which can reintensify over the downwind lake Upwind lakes do not always lead to an increase of precipitation downwind 7 Synoptic forcing Edit Vorticity advection aloft and large upscale ascent help increase mixing and the convective depth while cold air advection lowers the temperature and increases instability 8 Orography and topography Edit Typically lake effect precipitation increases with elevation to the lee of the lake as topographic forcing squeezes out precipitation and dries out the squall much faster 9 Snow and ice cover Edit As a lake gradually freezes over its ability to produce lake effect precipitation decreases for two reasons Firstly the open ice free liquid surface area of the lake shrinks This reduces fetch distances Secondly the water temperature nears freezing reducing overall latent heat energy available to produce squalls To end the production of lake effect precipitation a complete freeze is often not necessary 10 Even when precipitation is not produced cold air passing over warmer water may produce cloud cover Fast moving mid latitude cyclones known as Alberta clippers often cross the Great Lakes After the passage of a cold front winds tend to switch to the northwest and a frequent pattern is for a long lasting low pressure area to form over the Canadian Maritimes which may pull cold northwestern air across the Great Lakes for a week or more commonly identified with the negative phase of the North Atlantic Oscillation NAO Since the prevailing winter winds tend to be colder than the water for much of the winter the southeastern shores of the lakes are almost constantly overcast leading to the use of the term the Great Gray Funk as a synonym for winter citation needed These areas allegedly contain populations that suffer from high rates of seasonal affective disorder a type of psychological depression thought to be caused by lack of light 11 citation needed Great Lakes region EditUnited States Edit Lake effect snow bands over Central New York Map showing some of the lake effect snow areas of the United States Cold winds in the winter typically prevail from the northwest in the Great Lakes region producing the most dramatic lake effect snowfalls on the southern and eastern shores of the Great Lakes This lake effect results in much greater snowfall amounts on the southern and eastern shores compared to the northern and western shores of the Great Lakes The most affected areas include the Upper Peninsula of Michigan Central New York Western New York Northwestern Pennsylvania Northeastern Ohio southwestern Ontario and central Ontario Northeastern Illinois along the shoreline of Lake Michigan northwestern and north central Indiana mostly between Gary and Elkhart northern Wisconsin near Lake Superior and West Michigan Tug Hill in New York s North Country region has the second most snow amounts of any nonmountainous location within the continental U S trailing only the Upper Peninsula which can average over 200 in 508 cm of snow per year 12 Lake effect snows on the Tug Hill plateau east of Lake Ontario can frequently set daily records for snowfall in the United States Tug Hill receives typically over 20 feet 240 in 610 cm of snow each winter 13 In February 2007 a prolonged lake effect snow event left 141 inches 358 cm of snow on the Tug Hill Plateau 14 Syracuse New York directly south of the Tug Hill Plateau receives significant lake effect snow from Lake Ontario and averages 115 6 inches 294 cm of snow per year which is enough snowfall to be considered one of the snowiest large cities in America 15 16 A small amount of lake effect snow from the Finger Lakes falls in upstate New York as well If the wind blows almost the entire length of either Cayuga Lake or Seneca Lake Ithaca or Watkins Glen respectively can have a small lake effect snowstorm Lake Erie produces a similar effect for a zone stretching from the eastern suburbs of Cleveland through Erie to Buffalo 17 Remnants of lake effect snows from Lake Erie have been observed to reach as far south as Garrett County Maryland and as far east as Geneva New York 18 Because it is not as deep as the other lakes Erie warms rapidly in the spring and summer and is frequently the only Great Lake to freeze over in winter 19 Once frozen the resulting ice cover alleviates lake effect snow downwind of the lake Based on stable isotope evidence from lake sediment coupled with historical records of increasing lake effect snow global warming has been predicted to result in a further increase in lake effect snow 20 A very large snowbelt in the United States exists on the Upper Peninsula of Michigan near the cities of Houghton Marquette and Munising These areas typically receive 250 300 inches 635 762 cm of snow each season 21 For comparison on the western shore Duluth Minnesota receives 78 inches 198 cm per season 22 Lake Superior and Lake Huron rarely freeze because of their size and depth hence lake effect snow can fall continually in the Upper Peninsula and Canadian snowbelts during the winter Main areas of the Upper Peninsula snow belt include the Keweenaw Peninsula and Baraga Marquette and Alger Counties where Lake Superior contributes to lake effect snow making them a prominent part of the Midwestern snow belt Records of 390 inches 991 cm of snow or more have been set in many communities in this area The Keweenaw Peninsula averages more snowfall than almost anywhere in the United States more than anywhere east of the Mississippi River and most of all nonmountainous regions of the continental United States Because of the howling storms across Lake Superior which cause dramatic amounts of precipitation the lake effect snow is said to make the Keweenaw Peninsula the snowiest place east of the Rockies Only one official weather station exists in this region Located in Hancock Michigan this station averages well over 210 inches 533 cm per year Farther north in the peninsula lake effect snow can occur with any wind direction The road commission in Keweenaw County Michigan collects unofficial data in a community called Delaware and it strictly follows the guidelines set forth by the National Weather Service This station averages over 240 inches 610 cm per season Even farther north a ski resort called Mount Bohemia receives an unofficial annual average of 273 inches 693 cm Herman Michigan averages 236 inches 599 cm of snow every year Lake effect snow can cause blinding whiteouts in just minutes and some storms can last days Western Michigan western Northern Lower Michigan and Northern Indiana can get heavy lake effect snows as winds pass over Lake Michigan and deposit snows over Muskegon Traverse City Grand Rapids Kalamazoo New Carlisle South Bend and Elkhart but these snows abate significantly before Lansing or Fort Wayne Indiana When winds become northerly or aligned between 330 and 390 a single band of lake effect snow may form which extends down the length of Lake Michigan This long fetch often produces a very intense yet localized area of heavy snowfall affecting cities such as La Porte and Gary 23 Lake effect snow is uncommon in Detroit Toledo Milwaukee and Chicago because the region s dominant winds are from the northwest making them upwind from their respective Great Lakes although they too can see lake effect snow during easterly or northeasterly winds More frequently the north side of a low pressure system picks up more moisture over the lake as it travels east creating a phenomenon called lake enhanced precipitation 23 Buffalo New York after 82 3 inches 209 cm of snow fell from December 24 2001 to December 28 2001 Fulton New York after a snowburst dropped 4 6 feet 122 183 cm of snow over most of Oswego County January 28 31 2004 The Veteran s Day storm of November 9 14 1996 may be the most severe early season lake effect snow storm the Great Lakes has witnessed in the past 50 years At the height of the storm over 160 000 customers were without power in Greater Cleveland alone as the storm produced isolated snowfall tallies approaching 70 inches 178 cm Ontario Canada Edit Visible satellite image showing a large single lake effect band from Lake Huron with vigorous vertical motion This band produced 8 inches 20 cm of snow in the eastern and northern suburbs of Toronto Ontario The community of Wasaga Beach after 60 cm 24 in of snow fell in 12 hours from a persistent lake effect band Because Southwestern Ontario is surrounded by water on three sides many parts of Southwestern and Central Ontario get a large part of their winter snow from lake effect snow 24 This region is notorious for the whiteouts that can suddenly reduce highway visibility on North America s busiest highway Ontario Highway 401 25 from clear to zero The region most commonly affected spans from Port Stanley in the west the Bruce Peninsula in the north Niagara on the Lake to the east and Fort Erie to the south The heaviest accumulations usually happen in the Bruce Peninsula which is between Lake Huron and Georgian Bay So long as the Great Lakes are not frozen over the only time the Bruce Peninsula does not get lake effect snow is when the wind is directly from the south Toronto and Hamilton are usually spared lake effect squalls because they are not on the leeward side of Lake Ontario during the dominant northwest winds Some central and northern portions of the Greater Toronto Area though can be affected a few times each year by lake effect snow from Georgian Bay Downtown Toronto and Hamilton get most of their lake effect snow when the wind comes from the southeast or east over Lake Ontario Such easterly winds are usually associated with a winter cyclone passing just to the south of the Great Lakes When the wind is from the north the snowbelt runs north south from Grand Bend to Sarnia and London Areas such as Lucan and Kincardine have experienced some of the heaviest snowsqualls from Lake Huron in this region When the wind is slightly more westerly the snowbelt runs from Tobermory Owen Sound and Grand Bend to as far south and east as Arthur Orangeville and Caledon This snowbelt often reaches Kitchener and can affect the Halton and Peel regions of the Greater Toronto Area These northwesterly winds usually also bring snow southeast of Georgian Bay which can reach beyond Lake Scugog A westerly wind sends lake effect streamers east from Owen Sound to Gravenhurst Barrie and Orillia and may even reach as far south and east as York Region in the Greater Toronto Area When the wind is from the southwest lake effect streamers from Lake Huron and Georgian Bay run from Noelville to Sudbury Gravenhurst and Algonquin Provincial Park Winds from this same direction coming over Lake Ontario cause squalls to come ashore from Cobourg through the Belleville area to Kingston and the Thousand Islands with Prince Edward County being the area most vulnerable to extreme snowfall amounts Some snow bands can occasionally reach Quebec and Maine while snow originating from Lake Erie Lake Ontario and even Lake Michigan can impact southern Ontario Easterly winds primarily affect the Niagara Peninsula Local lake effect snowsqualls can occasionally occur downwind of Lake Simcoe when the lake is unfrozen usually in early winter or late fall Lake Superior has its own independent snowbelts affecting Wawa Sault Ste Marie Marathon the Keweenaw Peninsula in Upper Michigan and Pukaskwa National Park Thunder Bay is usually not affected by lake effect snow unless it is associated with a winter storm Elsewhere in the United States EditSee also Great Salt Lake effect The southern and southeastern sides of the Great Salt Lake receive significant lake effect snow Since the Great Salt Lake never freezes the lake effect can influence the weather along the Wasatch Front year round The lake effect largely contributes to the 55 80 inches 140 203 cm annual snowfall amounts recorded south and east of the lake and in average snowfall reaching 500 inches 13 m in the Wasatch Range The snow which is often very light and dry because of the semiarid climate is referred to as the Greatest Snow on Earth in the mountains Lake effect snow contributes to roughly six to eight snowfalls per year in Salt Lake City with about 10 of the city s precipitation being contributed by the phenomenon 26 Similar snowfall can occur near large inland bays where it is known as bay effect snow Bay effect snows fall downwind of Delaware Bay Chesapeake Bay and Massachusetts Bay when the basic criteria are met and on rarer occasions along Long Island The Finger Lakes of New York are long enough for lake effect precipitation The Texas twin cities of Sherman and Denison are known in rare instances to have experienced lake effect snow from nearby Lake Texoma due to the lake s size it is the third largest lake in Texas or along its borders On one occasion in December 2016 lake effect snow fell in central Mississippi from a lake band off Ross Barnett Reservoir 27 Oklahoma City even had a band of lake effect snow off of Lake Hefner in February 2018 Owasso Collinsville Oklahoma outside of Tulsa had lake effect snow off Lake Oolagah during a winter storm in February 2021 The Truckee Meadows and other parts of northern Nevada which are normally in the rain shadow of the Sierra Nevada when conditions are right can have severe snowfall as a result of lake effect from Lake Tahoe Recent severe examples of this phenomenon have occurred as recently as 2004 dumping several feet of snow in the normally dry region The West Coast occasionally experiences ocean effect showers usually in the form of rain at lower elevations south of about the mouth of the Columbia River These occur whenever an Arctic air mass from western Canada is drawn westward out over the Pacific Ocean typically by way of the Fraser Valley returning shoreward around a center of low pressure Cold air flowing southwest from the Fraser Valley can also pick up moisture over the Strait of Georgia and Strait of Juan de Fuca then rise over the northeastern slopes of the Olympic Mountains producing heavy localized snow between Port Angeles and Sequim as well as areas in Kitsap County and the Puget Sound region 28 While snow of any type is very rare in Florida the phenomenon of gulf effect snow has been observed along the northern coast of the Gulf of Mexico a few times in history More recently ocean effect snow occurred on January 24 2003 when wind off the Atlantic combined with air temperatures in the 30 F range brought snow flurries briefly to the Atlantic Coast of northern Florida seen in the air as far south as Cape Canaveral 29 Elsewhere in Canada EditLake Winnipeg Lake Manitoba and Lake Winnipegosis in Manitoba historically have seen lake effect snow as early as late October and it is common throughout early to mid November Towards the end of November the lakes sufficiently cool and begin to freeze ending the lake effect snow A brief period of lake effect snow is also common near Great Bear Lake and Great Slave Lake in the Northwest Territories during early winter usually early to mid October the lake effect season for both lakes is very short though The lakes are frozen roughly eight months of the year and as a result have very little time to warm during the summer Other small lakes such as Lake Athabasca in northern Saskatchewan and Lake Nipigon in northwestern Ontario produce early season lake effect snows Smallwood Reservoir a man made lake located in Labrador has on occasion generated lake effect snow The Canadian Maritimes specifically Nova Scotia and Prince Edward Island are often affected by such snow squalls when an Arctic winter airmass moves over unfrozen waters In PEI sea effect snow is often generated when a cold north wind blows over the unfrozen Gulf of St Lawrence dumping heavy snow on the north shore In Nova Scotia a cold north west wind can produce sea effect snow over the Cape Breton Highlands from the Gulf of St Lawrence and the Annapolis Valley from the Bay of Fundy in the latter case the sea effect snow season can continue all winter as the Bay of Fundy remains open owing to its extreme tidal currents The east coast of southern Vancouver Island British Columbia experiences occasional episodes of sea effect snow during winter due to cold easterly outflow winds from the British Columbia interior typically through the Fraser Valley crossing the always open waters of the Strait of Georgia Eurasia EditLake effect or sea effect snow occurs in other countries near large lakes or large sea areas In Eurasia it occurs in the regions of the Black Sea in Georgia Romania Bulgaria and northern Turkey the Caspian Sea in Iran the Adriatic Sea in Italy the North Sea the Irish Sea the Aegean Sea the Balearic Islands and the Baltic Sea as well as areas surrounding the Sea of Japan Because the southern Black Sea is relatively warm around 13 C or 55 F at the beginning of winter typically 10 to 6 C or 50 to 43 F by the end sufficiently cold air aloft can create significant snowfalls in a relatively short period of time Due to its location on a peninsula between the Black Sea and the Sea of Marmara Istanbul is very prone to lake effect snow and this weather phenomenon occurs almost every winter This type of precipitation is generated by the warmer Black Sea temperature and colder air temperature over the Istanbul area In February 2005 a lake effect snowfall left 50 cm 20 in of snow and in March 1987 a three week long lake effect snowfall accompanied with strong winds lake effect blizzard left 80 cm 31 in of snow in Istanbul 30 The snowfall in the eastern regions of the Black Sea is amplified by the orographic effect of the nearby Caucasus Mountains often resulting in snowfall of several meters especially at higher elevations In the Adriatic regions of Italy and in the eastern Apennine Mountains the sea effect snow phenomenon with air masses coming from Northern or Eastern Europe and Russia can be incredibly heavy and can last for days In the hills and mountains it can result in snowfalls of several meters as it happened in February 2012 These huge amounts of snow can also fall in short periods of time In Northern Europe cold dry air masses from Russia can blow over the Baltic Sea and cause heavy snow squalls on areas of the southern and eastern coasts of Sweden as well as on the Danish island of Bornholm the east coast of Jutland and the northern coast of Poland For the northern parts of the Baltic Sea this happens mainly in the early winter since it freezes later Southeast Norway can also experience heavy sea snow events with east north easterly winds Especially coastal areas from Kragero to Kristiansand have had incredible snow depths in the past with intense persistent snowbands from Norwegian Sea the coastal city of Arendal recorded 280 cm 110 in in a single week in late February 2007 31 Although Fennoscandia is lined with an abundance of lakes this type of snowfall is rare in these due to the shallow freshwater freezing early in the cold interiors One notable exception happened in the middle of May 2008 as Leksand on the since long unfrozen lake of Siljan got 30 cm 12 in on the ground 32 The Sea of Japan creates snowfall in the mountainous western Japanese prefectures of Niigata and Nagano parts of which are known collectively as snow country Yukiguni In addition to the Sea of Japan other parts of Japan as well as Korea and Shandong Peninsula 33 experience these same conditions Because the Aegean Sea Greece is warm in the winter when cold air masses from Siberia advance in the area they pick up much moisture resulting in heavy snowfalls in eastern Central Greece eastern Thessaly eastern Peloponnese south eastern Chalkidiki the Cyclades and Crete more commonly in the mountainous areas In 2008 a severe snowstorm blanketed Athens dropping 40 cm 16 in of snow and causing huge traffic jams Moving of polar or Siberian high pressure centers along Caspian Sea regarding to relatively warmer water of this sea can make heavy snowfalls in the northern coast of Iran Several blizzards have been reported in this region during the last decades In February 2014 heavy snowfall reached 200 cm 79 in on the coastline in Gilan and Mazandaran provinces of Iran The heaviest snowfall was reported in Abkenar village near Anzali Lagoon 34 35 36 37 IRIMO 38 radar animation of lake effect snow in southern coast of Caspian Sea in the north of Iran Lake effect clouds over Caspian Sea on January 7 2008 Lake effect snow in Athens on February 16 2021 Lake effect snow in Athens on February 16 2021United Kingdom EditIn the United Kingdom easterly winds bringing cold continental air across the North Sea can lead to a similar phenomenon Locally it is also known as lake effect snow despite the snow coming in from the sea rather than a lake 39 Similarly during a north westerly wind snow showers can form coming in from the Liverpool Bay coming down the Cheshire gap causing snowfall in the West Midlands this formation resulted in the white Christmas of 2004 in the area and most recently the heavy snowfall of 8 December 2017 and 30 January 2019 40 41 A similar phenomenon can affect the city of Inverness in the Scottish Highlands where cold north east winds cause heavy snow to form in the Moray Firth this was the case with the White Hogmanay of 2009 which caused the street party to be cancelled Northerly and north westerly winds can cause the effect to occur over the Irish Sea and Bristol Channel feeding snow into South West England and eastern Ireland Western Scotland and northern Ireland can also see snow showers from a north or north westerly wind over the Atlantic Since the North Sea is relatively warm around 13 C or 55 4 F at the beginning of winter typically 10 to 6 C or 50 to 43 F by the end sufficiently cold air aloft can create significant snowfalls in a relatively short period of time The best known example occurred in January 1987 when record breaking cold air associated with an upper low moved across the North Sea towards the UK The end result was over 2 ft of snow for coastal areas leading to communities being cut off for over a week The latest of these events to affect Britain s east coast occurred on November 30 2017 February 28 2018 and March 17 2018 in connection with the 2018 Great Britain and Ireland cold wave 42 The second event of winter 2017 18 was particularly severe with up to 27 5 inches 70 cm falling in total over the 27th 28th 43 Similarly northerly winds blowing across the relatively warm waters of the English Channel during cold spells can bring significant snowfall to the French region of Normandy where snow drifts exceeding 10 ft 3 m were measured in March 2013 44 Chart showing the sea effect snow event of January 1987 in the UK A continuous stream of showers deposited over 2 feet 24 in of snow over SE coastal regions NetWeather 45 radar image showing lake effect snow over Kent and northeast EnglandSee also EditHorizontal convective rolls Ontario winter lake effect systems Planetary boundary layer Sea smokeWarnings about lake effect snow United States Lake effect snow advisory Lake effect snow watch Lake effect snow warning Severe weather terminology United States dd Canada Snowsquall warning Severe weather terminology Canada dd References Edit Warm Water and Cold Air The Science Behind Lake Effect Snow National Oceanic and Atmospheric Administration Archived from the original on January 2 2015 Retrieved January 2 2015 WFO Winter Weather Products Specification PDF National Weather Service May 7 2020 Archived PDF from the original on August 18 2006 Byrd Greg June 3 1998 Lake Effect Snow Instability University Corporation for Atmospheric Research Archived from the original on June 17 2009 Byrd Greg June 3 1998 Lake Effect Snow Fetch University Corporation for Atmospheric Research Archived from the original on May 15 2008 a b Byrd Greg June 3 1998 Lake Effect Snow Wind Shear University Corporation for Atmospheric Research Archived from the original on May 11 2008 Byrd Greg June 3 1998 Lake Effect Snow Upstream Moisture University Corporation for Atmospheric Research Archived from the original on May 9 2008 Byrd Greg June 3 1998 Lake Effect Snow Upstream Lakes University Corporation for Atmospheric Research Archived from the original on May 9 2008 Byrd Greg June 3 1998 Lake Effect Snow Synoptic Scale Forcing University Corporation for Atmospheric Research Archived from the original on May 16 2008 Byrd Greg June 3 1998 Lake Effect Snow Orography Topography University Corporation for Atmospheric Research Archived from the original on May 9 2008 Byrd Greg June 3 1998 Lake Effect Snow Snow Ice Cover on the Great Lakes University Corporation for Atmospheric Research Archived from the original on May 15 2008 Health Advisories Weather and Mood The Weather Underground Archived from the original on February 21 2007 Retrieved January 4 2007 Mean Monthly and Annual Snowfall for the Conterminous United States The Climate Source 2003 Archived from the original on June 9 2008 Tug Hill Plateau New York Northern Forest Alliance Archived from the original on May 9 2008 Retrieved February 1 2015 Climate of 2007 February in Historical Perspective National Climatic Data Center March 15 2007 Archived from the original on December 21 2007 Retrieved March 1 2008 Cappella Chris October 3 2003 Answers 10 snowiest cities aren t all in New York USA Today Archived from the original on October 12 2011 Kirst Sean March 14 2005 We won t buckle under the Snowbelt s blows The Post Standard Schmidlin Thomas W 1989 Climatic Summary of Snowfall and Snow Depth in the Ohio Snowbelt at Chardon PDF The Ohio Journal of Science 89 4 101 108 Archived PDF from the original on July 16 2007 Retrieved March 1 2008 February Brings Winter Weather to the Northeast Northeast Regional Climate Center February 1995 Archived from the original on June 11 2007 Retrieved March 1 2008 Introduction to the Great Lakes Lake Erie Great Lakes Information Network Archived from the original on May 9 2008 Retrieved March 1 2008 Burnett Adam W Kirby Matthew E Mullins Henry T Patterson William P 2003 Increasing Great Lake Effect Snowfall during the Twentieth Century A Regional Response to Global Warming Journal of Climate 16 21 3535 3542 Bibcode 2003JCli 16 3535B doi 10 1175 1520 0442 2003 016 lt 3535 IGLSDT gt 2 0 CO 2 S2CID 58935593 Ruhf Robert J Lake Effect Precipitation in Michigan Dr Robert J Ruhf Retrieved March 1 2008 Average Snowfall Inches University of Utah Department of Meteorology Archived from the original on February 12 2008 Retrieved March 1 2008 a b Lake effect Snow in the Great Lakes Region Great Lakes Integrated Sciences and Assessments Archived from the original on April 13 2014 Retrieved April 10 2014 Scott Cameron December 14 2010 How Lakes Affect Snowfalls Sciences360 com Jennings Ken June 18 2018 The World s Widest Highway Spans a Whopping 26 Lanes Conde Nast Traveler Retrieved February 17 2021 Bauman Joe August 5 1999 Lake has great impacts on storm weather Deseret News Archived from the original on October 2 2012 Hutton Brian December 20 2016 Tuesday December 20 Afternoon Forecast Discussion WTOK TV Mass Cliff 2008 The Weather of the Pacific Northwest University of Washington Press p 60 ISBN 978 0 295 98847 4 Cold Temperatures and Snow Flurries in East Central Florida January 24 2003 PDF National Weather Service Office Melbourne Florida Archived PDF from the original on January 27 2017 Retrieved November 5 2006 Kindap T amp Gokturk O M 2006 The Black Sea impact on the severe snow episode over the city of Istanbul PDF Geophysical Research Abstracts 8 Archived PDF from the original on July 29 2014 Rapport om vaer og foreforhold i Agder i perioden 20 28 februar 2007 Report on weather and driving conditions in Agder in the period 20 28 February 2007 Statens vegvesen State Highways Authority in Norwegian May 1 2007 Archived from the original on October 25 2019 Retrieved October 25 2019 Maj 2008 Bade sommarvarme och sent snofall in Swedish Swedish Meteorological and Hydrological Institute June 2 2008 Retrieved March 31 2022 Bao Baoleerqimuge amp Ren Guoyu May 2018 Sea Effect Precipitation over the Shandong Peninsula Northern China Journal of Applied Meteorology and Climatology 57 6 1291 1308 Bibcode 2018JApMC 57 1291B doi 10 1175 JAMC D 17 0200 1 S2CID 126039299 Snow Blankets Iran NASA Earth Observatory February 11 2014 Iran snow cuts power to nearly 500 000 homes BBC News February 3 2014 Heavy Snow Kills Dozens in Asia National Geographic January 10 2008 Archived from the original on July 24 2008 Iranians use Facebook to save villagers from snowstorm The Observers France 24 February 14 2014 Archived from the original on February 22 2014 Retrieved February 14 2014 سازمان هواشناسی Weather in Persian Iran Meteorological Organization Archived from the original on August 29 2014 Retrieved January 1 2022 Conversations uk sci weather archives Retrieved August 3 2007 Snow closes schools in Greater Manchester plus city airports BBC News January 30 2019 Rowden Nathan December 8 2017 Heavy snow causes chaos in Shropshire and there s more on the way Shropshire Star Snow falls on England s east coast beaches BBC News November 30 2017 Hopewell John February 28 2018 Brutal storm is pummeling Britain with heavy snow and wicked wind chill The Washington Post Neige Le mois de mars de tous les records en Normandie Snow The month of March of all records in Normandy actu fr in French March 14 2013 Archived from the original on December 3 2013 Retrieved November 26 2013 Netweather netweather tv External links Edit Wikimedia Commons has media related to Lake effect snow National Weather Service Official Lake Effect Page based in Buffalo NY Lake effect forecasting Video of a snowsquall timelapse while driving on Highway 407 ETR in Greater Toronto Digital Snow Museum Ice and snow measurements on lakes and surrounding land areas Archived 2010 05 27 at the Wayback Machine Great Lakes Environmental Research Laboratory A BBC forecast of lake effect snow in the UK in 1991 Retrieved from https en wikipedia org w index php title Lake effect snow amp oldid 1132171861, wikipedia, wiki, book, books, library,

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