Frontal dynamics near the following frontal collapse

C. Snyder; W. C. Skamarock; R. Rotunno

doi:10.1175/1520-0469(1993)050<3194:FDNAFF>2.0.CO;2

Frontal dynamics near the following frontal collapse

C. Snyder, W. C. Skamarock, R. Rotunno

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115 Scopus citations

Abstract

A nonhydrostatic numerical model is used to simulate two-dimensional frontogenesis forced by either horizontal deformation or shear. Both inviscid frontogenesis prior to frontal collapse and frontogenesis with horizontal diffusion following collapse are considered. Certain deviations from SG that have been previously discussed in the literature are, upon closer examination, associated with spurious gravity waves produced by inadequate resolution or by the initialization of the numerical model. Even when spurious waves are eliminated, however, significant deviations from SG still exist: gravity waves are emitted by the frontogenesis when the cross-front scale becomes sufficiently small, and higher-order corrections to SG may also be present. In the postcollapse solutions (where they are most prominent), the emitted waves are stationary with respect to the front and lead to a band of increased low-level ascent just ahead of the surface front. -from Authors

Original language	English
Pages (from-to)	3194-3212
Number of pages	19
Journal	Journal of the Atmospheric Sciences
Volume	50
Issue number	18
DOIs	https://doi.org/10.1175/1520-0469(1993)050<3194:FDNAFF>2.0.CO;2
State	Published - 1993

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10.1175/1520-0469(1993)050<3194:FDNAFF>2.0.CO;2

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title = "Frontal dynamics near the following frontal collapse",

abstract = "A nonhydrostatic numerical model is used to simulate two-dimensional frontogenesis forced by either horizontal deformation or shear. Both inviscid frontogenesis prior to frontal collapse and frontogenesis with horizontal diffusion following collapse are considered. Certain deviations from SG that have been previously discussed in the literature are, upon closer examination, associated with spurious gravity waves produced by inadequate resolution or by the initialization of the numerical model. Even when spurious waves are eliminated, however, significant deviations from SG still exist: gravity waves are emitted by the frontogenesis when the cross-front scale becomes sufficiently small, and higher-order corrections to SG may also be present. In the postcollapse solutions (where they are most prominent), the emitted waves are stationary with respect to the front and lead to a band of increased low-level ascent just ahead of the surface front. -from Authors",

author = "C. Snyder and Skamarock, \{W. C.\} and R. Rotunno",

year = "1993",

doi = "10.1175/1520-0469(1993)050<3194:FDNAFF>2.0.CO;2",

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journal = "Journal of the Atmospheric Sciences",

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T1 - Frontal dynamics near the following frontal collapse

AU - Snyder, C.

AU - Skamarock, W. C.

AU - Rotunno, R.

PY - 1993

Y1 - 1993

N2 - A nonhydrostatic numerical model is used to simulate two-dimensional frontogenesis forced by either horizontal deformation or shear. Both inviscid frontogenesis prior to frontal collapse and frontogenesis with horizontal diffusion following collapse are considered. Certain deviations from SG that have been previously discussed in the literature are, upon closer examination, associated with spurious gravity waves produced by inadequate resolution or by the initialization of the numerical model. Even when spurious waves are eliminated, however, significant deviations from SG still exist: gravity waves are emitted by the frontogenesis when the cross-front scale becomes sufficiently small, and higher-order corrections to SG may also be present. In the postcollapse solutions (where they are most prominent), the emitted waves are stationary with respect to the front and lead to a band of increased low-level ascent just ahead of the surface front. -from Authors

AB - A nonhydrostatic numerical model is used to simulate two-dimensional frontogenesis forced by either horizontal deformation or shear. Both inviscid frontogenesis prior to frontal collapse and frontogenesis with horizontal diffusion following collapse are considered. Certain deviations from SG that have been previously discussed in the literature are, upon closer examination, associated with spurious gravity waves produced by inadequate resolution or by the initialization of the numerical model. Even when spurious waves are eliminated, however, significant deviations from SG still exist: gravity waves are emitted by the frontogenesis when the cross-front scale becomes sufficiently small, and higher-order corrections to SG may also be present. In the postcollapse solutions (where they are most prominent), the emitted waves are stationary with respect to the front and lead to a band of increased low-level ascent just ahead of the surface front. -from Authors

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DO - 10.1175/1520-0469(1993)050<3194:FDNAFF>2.0.CO;2

M3 - Article

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VL - 50

SP - 3194

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JO - Journal of the Atmospheric Sciences

JF - Journal of the Atmospheric Sciences

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ER -

Frontal dynamics near the following frontal collapse

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