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Meteorología sinóptica Lección 10: frontogénesis Courtesy: Lyndon State College What is a front? • Early meteorological theory thought that “fronts” led to development of low pressure systems (cyclones) – However, in the 1940s, “baroclinic instability theory” found that cyclones can form away from fronts, then develop frontal features • So what is a front? – Several definitions exist: • Zone of “enhanced” temperature gradient (but what constitutes “enhanced”?) • Sharp transition in air masses – The Great Plains dry line is a sharp change in air masses but is not considered a front • Zone of density differences – But density is driven by not only temperature but also moisture and pressure – Example: • Early a.m. clear skies, NW winds, & cold air over Oklahoma, and cloudy skies, SE winds, and warm air over Arkansas. A cold front separates the two. • By mid-day, solar radiation has strongly heated the air over Oklahoma, and it is now warmer than the moist air over Arkansas. Has the front disappeared? Changed to a warm front? A basic definition • Following Lackmann (2012), we will use the following definition of a front: – A boundary between air masses • Recognize that all boundaries between air masses may not be fronts – Examples: semi-permanent thermal gradients locked in place by topographic boundaries, land-sea contrasts • How do we proceed? – In weather chart analyzes, be sure to analyze temperature • The important boundaries will then be evident on the chart Properties of fronts • Most defining property (on a weather map): enhanced horizontal gradients of temperature – Usually long and narrow: synoptic scale (1000 km) in the along-front direction, mesoscale (100 km) in the across-front direction • Other properties: – Pressure minimum and cyclonic vorticity maximum along the front – Strong vertical wind shear • Exists because of horizontal temperature gradients (required by “thermal wind balance” – Large static stability within the front – Ageostrophic circulations • Rising motion on the warm side of the frontal boundary • Sinking motion on the cool side of the boundary – Greatest intensity at the bottom, weakening with height • Fronts are mostly confined near the surface, but not always – Upper-level fronts, i.e. gradients of temperature aloft, are associated with strong vertical wind shear • Clear-air turbulence and aviation hazards often occur there Example of a front: 17 Nov 2009 Sea-level pressure (mb) 950-mb relative vorticity (s-1) Potential temp (k) Cross-section of potential temp (k) and wind Frontogenesis function • To examine whether a front is strengthening or weakening, can look at the “Frontogenesis Function” – When F is positive, frontogenesis is occurring – When F is negative, frontolysis is occurring • F allows for examination of the different physical mechanisms that lead to changes in temperature gradients u v d F x y y y p y y dt Shearing Confluence • Let’s examine each term in turn Tilting Diabatic heating Shearing term • Shear frontogenesis describes the change in front strength due to differential temperature advection by the front-parallel wind component x u y – Along the cold front, both and are negative, giving a positive contribution to F (note the rotation of the coordinate system!!) – This means cold-air advection in the cold air, and warm-air advection in the warm air. t=0 t=+24 Example: positive contribution to F along the cold front: shearing frontogenesis Shearing term • Shear frontogenesis describes the change in front strength due to differential temperature advection by the front-parallel wind component u – Along the warm front, x is positive, but y is negative, giving a negative contribution to F (again note the rotation of the coordinate system!!) – This means along the warm front, shearing acts in a frontolytical sense t=0 t=+24 Example: negative contribution to F along the warm front: shearing frontolysis Confluence term • Confluence frontogenesis describes the change in front strength due to stretching. If the isotherms are stretching (spreading out), there is frontolysis. If they are compacting, frontogenesis is occurring. v – Along the front, y is negative. Here y is also negative, giving a positive contribution to F (again note the rotation of the coordinate system!!) – This means along the front, confluence acts in a frontogenetical sense t=0 t=+24 Example: positive contribution to F along the front: confluence frontogenesis Tilting term • Near the Earth’s surface, vertical motion is usually fairly small – But higher aloft, it can be strong • Thus tilting usually acts to strengthen fronts above the Earth’s surface • Consider the following example: here, p is positive (temperature decreases above the surface), and y is also positive (rising motion in the cold air, sinking in the warm air) z z y Example: positive contribution to F along a front: tilting y Diabatic heating term • The differential diabatic heating term takes into account all diabatic processes together: – Differential solar radiation, differential surface heating due to soil characteristics, differential heat surface flux • One example: differential solar radiation – Assume the diabatic heating rate in the warm air exceeds the diabatic heating rate in the cold air d – In that example, y dt would be positive, and F positive Example: positive contribution to F along a front: differential diabatic heating Frontal circulations • • Important terminology: – Thermally direct: warm air rises, cold air sinks – Thermally indirect: warm air sinks, cold air rises – Ageostrophic: departure from geostrophic flow Because of the strong temperature contrasts along fronts, there are often thermally direct circulations: warm air rises, cold air sinks – The rising / sinking motions are ageostrophic, and by themselves, act to weaken fronts • See the tilting term example • Also, lifting air cools it (so the warm air cools) and sinking air warms (so the cold air warms) – But when ageostrophic circulations act together with geostrophic flow above the surface, they can act to strengthen the front at the surface Example: geostrophic and ageostrophic flows strengthening a front at the surface Cold fronts • Defined as: – Clear advance of cold airmass with time • Usually characterized by: – Abrupt wind shift from a southerly component to a westerly or northerly component – Pressure falls before, then rises after, passage – Showers and sometimes thunderstorms • Two types: – Katafront, with precipitation ahead of the front • • Usually preceeded by a cold front (or boundary) aloft Front slopes forward – Anafront, with precipitation behind the front • Arrows represent direction of upper-level winds; hatching in katafront figure indicates precipitation area Front slopes backward Anafront Katafront Source: Browning 1986 Warm fronts • Defined as: – Clear advance of warm airmass with time • Usually characterized by: – Gradual wind shift from easterly to southerly during passage – Turbulent mixing along the passage • Gives rise to risk of tornadic thunderstorms along front – Shallow vertical slope Occluded fronts • Cyclogenesis is favored along frontal boundaries – Rich area of cyclonic vorticity – Rising motion (and vorticity stretching) • Circulation around surface cyclone moves air masses – We call these boundaries fronts • Cold front moves faster than warm front – What happens when the cold front “catches up” to the warm front? • The resulting boundary (between cold and not so cold air) is called an occluded front • Noted on surface charts by purple symbol with both triangles and semi-circles in same direction Sistemas que actúan como frentes: “squall lines” Fuente: Browning 1986 Otros sistemas asociados con ciclones extratropicales Fuente: Browning 1986