Editing Avalanche (section)

=== Weather ===
{{More citations needed section|date=June 2021}}
[[File:Avalanche testing snow pit.JPG|thumb|left|After digging a snow pit, it is possible to evaluate the snowpack for unstable layers. In this picture, snow from a weak layer has been easily scraped away by hand, leaving a horizontal line in the wall of the pit.]]
Avalanches only occur in a standing snowpack. Typically winter seasons at high latitudes, high altitudes, or both have weather that is sufficiently unsettled and cold enough for precipitated snow to accumulate into a seasonal snowpack. [[Continentality]], through its potentiating influence on the meteorological extremes experienced by snowpacks, is an important factor in the evolution of instabilities, and consequential occurrence of avalanches faster stabilization of the snowpack after storm cycles.<ref>Whiteman, Charles David: ''Mountain Meteorology: Fundamentals and Applications'', Oxford University Press: 2001. {{ISBN|0-19-513271-8}}</ref> The evolution of the snowpack is critically sensitive to small variations within the narrow range of meteorological conditions that allow for the accumulation of snow into a snowpack. Among the critical factors controlling snowpack evolution are: heating by the sun, [[radiational cooling]], vertical [[temperature gradient]]s in standing snow, snowfall amounts, and snow types. Generally, mild winter weather will promote the settlement and stabilization of the snowpack; conversely, very cold, windy, or hot weather will weaken the snowpack.<ref>{{Cite web |last=US EPA |first=OAR |date=2016-07-01 |title=Climate Change Indicators: Snowpack |url=https://www.epa.gov/climate-indicators/climate-change-indicators-snowpack |access-date=2024-04-15 |website=www.epa.gov |language=en}}</ref>

At temperatures close to the freezing point of water, or during times of moderate solar radiation, a gentle freeze-thaw cycle will take place. The melting and refreezing of water in the snow strengthens the snowpack during the freezing phase and weakens it during the thawing phase. A rapid rise in temperature, to a point significantly above the freezing point of water, may cause avalanche formation at any time of year.<ref>{{Cite web |last=O'Neill |first=Donny |date=2021-04-12 |title=How Climate Change Impacts Avalanche Conditions |url=https://protectourwinters.org/how-does-climate-change-impact-avalanches/ |access-date=2024-04-10 |website=Protect Our Winters |language=en-US}}</ref>

Persistent cold temperatures can either prevent new snow from stabilizing or destabilize the existing snowpack. Cold air temperatures on the snow surface produce a temperature gradient in the snow, because the ground temperature at the base of the snowpack is usually around 0&nbsp;°C, and the ambient air temperature can be much colder. When a temperature gradient greater than 10&nbsp;°C change per vertical meter of snow is sustained for more than a day, angular crystals called [[depth hoar]] or facets begin forming in the snowpack because of rapid moisture transport along the temperature gradient. These angular crystals, which bond poorly to one another and the surrounding snow, often become a persistent weakness in the snowpack. When a slab lying on top of a persistent weakness is loaded by a force greater than the strength of the slab and persistent weak layer, the persistent weak layer can fail and generate an avalanche.{{fact|date=January 2024}}

Any wind stronger than a light breeze can contribute to a rapid accumulation of snow on sheltered slopes downwind. Wind slabs form quickly and, if present, weaker snow below the slab may not have time to adjust to the new load. Even on a clear day, wind can quickly load a slope with snow by blowing snow from one place to another. Top-loading occurs when wind deposits snow from the top of a slope; cross-loading occurs when wind deposits snow parallel to the slope. When a wind blows over the top of a mountain, the leeward, or downwind, side of the mountain experiences top-loading, from the top to the bottom of that lee slope. When the wind blows across a ridge that leads up the mountain, the leeward side of the ridge is subject to cross-loading. Cross-loaded wind-slabs are usually difficult to identify visually.{{fact|date=January 2024}}

Snowstorms and rainstorms are important contributors to avalanche danger. Heavy snowfall will cause instability in the existing snowpack, both because of the additional weight and because the new snow has insufficient time to bond to underlying snow layers. Rain has a similar effect. In the short term, rain causes instability because, like a heavy snowfall, it imposes an additional load on the snowpack and once rainwater seeps down through the snow, acts as a lubricant, reducing the natural friction between snow layers that holds the snowpack together. Most avalanches happen during or soon after a storm.{{fact|date=January 2024}}

Daytime exposure to sunlight will rapidly destabilize the upper layers of the snowpack if the sunlight is strong enough to melt the snow, thereby reducing its hardness. During clear nights, the snowpack can re-freeze when ambient air temperatures fall below freezing, through the process of long-wave radiative cooling, or both. Radiative heat loss occurs when the night air is significantly cooler than the snowpack, and the heat stored in the snow is re-radiated into the atmosphere.<ref>{{Cite web |title=Physical Properties of Snow |url=https://www.inscc.utah.edu/~campbell/snowdynamics/reading/Pomeroy.pdf |access-date=April 9, 2024 |website=University of Utah}}</ref>