The effects of a mountain on the propagation of a preexisting convective system for blocked and unblocked flow regimes

The effects of a mountain on the propagation of a preexisting convective system for blocked and unblocked flow regimes

Observations and previous research of squall lines impinging on mountain ranges have revealed that the squall lines sometimes stall upstream of the mountains for several hours leading to copious accumulations of precipitation. It has been hypothesized that squall-line stagnation may be more prone to...

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Veröffentlicht in:Journal of the atmospheric sciences 2007-07, Vol.64 (7), p.2401-2421
Hauptverfasser: DAWN REEVES, Heather, LIN, Yuh-Lang
Format: Artikel
Sprache:eng
Schlagworte:
Atmosphere
Brunt-Vaisala frequency
Cold
Convective systems
Design
Earth, ocean, space
Evaporative cooling
Exact sciences and technology
Experiments
External geophysics
Froude number
Hypotheses
Meteorology
Mountains
Physics of the high neutral atmosphere
Propagation
Simulation
Squall lines
Squalls
Stagnation
Surface roughness
Upstream
Velocity
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creator DAWN REEVES, Heather
LIN, Yuh-Lang
description Observations and previous research of squall lines impinging on mountain ranges have revealed that the squall lines sometimes stall upstream of the mountains for several hours leading to copious accumulations of precipitation. It has been hypothesized that squall-line stagnation may be more prone to occur in flows where the Froude number (F = U/Nh, where U is the basic-state wind, N is the Brunt–Väisälä frequency, and h is the mountain height) is low. This hypothesis is tested herein through a series of idealized, two-dimensional experiments where a convective system was triggered upstream of a mesoscale mountain in conditionally unstable flow. For simulations with relatively low Froude numbers, stagnation of the preexisting convective system was not observed. In the simulations with high values of F, squall lines were noted to stagnate between 100 and 200 km upstream of the mountain. This result indicates that squall-line stagnation may be more favored for moderate to large values of F for conditionally unstable flow. The mechanisms leading to the formation of the stationary convective system upstream of the mountain in the unblocked flows were explored and it was found that evaporative cooling played a pivotal role in the stagnation of the squall line.
doi_str_mv 10.1175/JAS3959.1
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It has been hypothesized that squall-line stagnation may be more prone to occur in flows where the Froude number (F = U/Nh, where U is the basic-state wind, N is the Brunt–Väisälä frequency, and h is the mountain height) is low. This hypothesis is tested herein through a series of idealized, two-dimensional experiments where a convective system was triggered upstream of a mesoscale mountain in conditionally unstable flow. For simulations with relatively low Froude numbers, stagnation of the preexisting convective system was not observed. In the simulations with high values of F, squall lines were noted to stagnate between 100 and 200 km upstream of the mountain. This result indicates that squall-line stagnation may be more favored for moderate to large values of F for conditionally unstable flow. 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source American Meteorological Society; EZB-FREE-00999 freely available EZB journals; Alma/SFX Local Collection
subjects Atmosphere
Brunt-Vaisala frequency
Cold
Convective systems
Design
Earth, ocean, space
Evaporative cooling
Exact sciences and technology
Experiments
External geophysics
Froude number
Hypotheses
Meteorology
Mountains
Physics of the high neutral atmosphere
Propagation
Simulation
Squall lines
Squalls
Stagnation
Surface roughness
Upstream
Velocity
title The effects of a mountain on the propagation of a preexisting convective system for blocked and unblocked flow regimes
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