Propagation properties of inertia-gravity waves through a barotropic shear layer and application to the Antarctic polar vortex

The propagation of inertia-gravity waves through a dynamical transport barrier, such as the Antarctic polar vortex edge is investigated using a linear wave model. The model is based on the linearized, inviscid hydrostatic equations on an f-plane. Typical values for the parameters that are appropriat...

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Published in:Quarterly Journal of the Royal Meteorological Society
Main Authors: Öllers, M.C., Kamp, L.P.J., Lott, F., Velthoven, van, P.F.J., Kelder, H.M., Sluijter, F.W.
Format: Article in Journal/Newspaper
Language:English
Published: 2003
Subjects:
Antarctic
The Antarctic
Antarc*
Online Access:https://research.tue.nl/en/publications/278d1297-ec36-4b0b-9c74-53cfc0d8b651
https://doi.org/10.1256/qj.02.98
id ftuniveindcris:oai:pure.tue.nl:publications/278d1297-ec36-4b0b-9c74-53cfc0d8b651
record_format openpolar
spelling ftuniveindcris:oai:pure.tue.nl:publications/278d1297-ec36-4b0b-9c74-53cfc0d8b651 2024-06-23T07:47:44+00:00 Propagation properties of inertia-gravity waves through a barotropic shear layer and application to the Antarctic polar vortex Öllers, M.C. Kamp, L.P.J. Lott, F. Velthoven, van, P.F.J. Kelder, H.M. Sluijter, F.W. 2003 https://research.tue.nl/en/publications/278d1297-ec36-4b0b-9c74-53cfc0d8b651 https://doi.org/10.1256/qj.02.98 eng eng https://research.tue.nl/en/publications/278d1297-ec36-4b0b-9c74-53cfc0d8b651 info:eu-repo/semantics/closedAccess Öllers , M C , Kamp , L P J , Lott , F , Velthoven, van , P F J , Kelder , H M & Sluijter , F W 2003 , ' Propagation properties of inertia-gravity waves through a barotropic shear layer and application to the Antarctic polar vortex ' , Quarterly Journal of the Royal Meteorological Society , vol. 129 , no. 593 , pp. 2495-2511 . https://doi.org/10.1256/qj.02.98 article 2003 ftuniveindcris https://doi.org/10.1256/qj.02.98 2024-05-29T23:46:21Z The propagation of inertia-gravity waves through a dynamical transport barrier, such as the Antarctic polar vortex edge is investigated using a linear wave model. The model is based on the linearized, inviscid hydrostatic equations on an f-plane. Typical values for the parameters that are appropriate to the Antarctic polar vortex are given. The background flow U is assumed to be barotropic and its horizontal shear is represented by a hyperbolic tangent background wind profile. The wave equation that describes the latitudinal structure of a monochromatic disturbance contains two singularities. The first corresponds to the occurrence of a critical level where the intrinsic wave frequency Omega = omega - kU becomes zero, omega is the absolute wave frequency and k its longitudinal wave number in the direction of U. The second is an apparent singularity and does not give rise to singular wave behaviour. It becomes zero whenever the square of the intrinsic wave frequency Omega /sup 2/ = f(f - U/sub y/), f being the Coriolis frequency and U/sub y/ the horizontal shear of the flow. The wave equation is solved numerically for different values of the angles of incidence of the wave upon the background flow, of the wave frequency, of the horizontal wave number and of the Rossby number. Reflection (|R|) and transmission (|T|) coefficients are determined as a function of these parameters. The results depend on whether the flow is inertially stable or not. They also depend on the presence and location of the turning levels, where the wave becomes evanescent, with respect to the location of the Q-critical levels. For inertially stable flows, the wave totally reflects at the turning level and never reaches the critical level. If the background flow is inertially unstable, turning levels can disappear and the wave can now reach the critical level. Then over-reflection, over-transmission and absorption can occur Article in Journal/Newspaper Antarc* Antarctic Eindhoven University of Technology research portal Antarctic The Antarctic Quarterly Journal of the Royal Meteorological Society 129 593 2495 2511
institution Open Polar
collection Eindhoven University of Technology research portal
op_collection_id ftuniveindcris
language English
description The propagation of inertia-gravity waves through a dynamical transport barrier, such as the Antarctic polar vortex edge is investigated using a linear wave model. The model is based on the linearized, inviscid hydrostatic equations on an f-plane. Typical values for the parameters that are appropriate to the Antarctic polar vortex are given. The background flow U is assumed to be barotropic and its horizontal shear is represented by a hyperbolic tangent background wind profile. The wave equation that describes the latitudinal structure of a monochromatic disturbance contains two singularities. The first corresponds to the occurrence of a critical level where the intrinsic wave frequency Omega = omega - kU becomes zero, omega is the absolute wave frequency and k its longitudinal wave number in the direction of U. The second is an apparent singularity and does not give rise to singular wave behaviour. It becomes zero whenever the square of the intrinsic wave frequency Omega /sup 2/ = f(f - U/sub y/), f being the Coriolis frequency and U/sub y/ the horizontal shear of the flow. The wave equation is solved numerically for different values of the angles of incidence of the wave upon the background flow, of the wave frequency, of the horizontal wave number and of the Rossby number. Reflection (|R|) and transmission (|T|) coefficients are determined as a function of these parameters. The results depend on whether the flow is inertially stable or not. They also depend on the presence and location of the turning levels, where the wave becomes evanescent, with respect to the location of the Q-critical levels. For inertially stable flows, the wave totally reflects at the turning level and never reaches the critical level. If the background flow is inertially unstable, turning levels can disappear and the wave can now reach the critical level. Then over-reflection, over-transmission and absorption can occur
format Article in Journal/Newspaper
author Öllers, M.C.
Kamp, L.P.J.
Lott, F.
Velthoven, van, P.F.J.
Kelder, H.M.
Sluijter, F.W.
spellingShingle Öllers, M.C.
Kamp, L.P.J.
Lott, F.
Velthoven, van, P.F.J.
Kelder, H.M.
Sluijter, F.W.
Propagation properties of inertia-gravity waves through a barotropic shear layer and application to the Antarctic polar vortex
author_facet Öllers, M.C.
Kamp, L.P.J.
Lott, F.
Velthoven, van, P.F.J.
Kelder, H.M.
Sluijter, F.W.
author_sort Öllers, M.C.
title Propagation properties of inertia-gravity waves through a barotropic shear layer and application to the Antarctic polar vortex
title_short Propagation properties of inertia-gravity waves through a barotropic shear layer and application to the Antarctic polar vortex
title_full Propagation properties of inertia-gravity waves through a barotropic shear layer and application to the Antarctic polar vortex
title_fullStr Propagation properties of inertia-gravity waves through a barotropic shear layer and application to the Antarctic polar vortex
title_full_unstemmed Propagation properties of inertia-gravity waves through a barotropic shear layer and application to the Antarctic polar vortex
title_sort propagation properties of inertia-gravity waves through a barotropic shear layer and application to the antarctic polar vortex
publishDate 2003
url https://research.tue.nl/en/publications/278d1297-ec36-4b0b-9c74-53cfc0d8b651
https://doi.org/10.1256/qj.02.98
geographic Antarctic
The Antarctic
geographic_facet Antarctic
The Antarctic
genre Antarc*
Antarctic
genre_facet Antarc*
Antarctic
op_source Öllers , M C , Kamp , L P J , Lott , F , Velthoven, van , P F J , Kelder , H M & Sluijter , F W 2003 , ' Propagation properties of inertia-gravity waves through a barotropic shear layer and application to the Antarctic polar vortex ' , Quarterly Journal of the Royal Meteorological Society , vol. 129 , no. 593 , pp. 2495-2511 . https://doi.org/10.1256/qj.02.98
op_relation https://research.tue.nl/en/publications/278d1297-ec36-4b0b-9c74-53cfc0d8b651
op_rights info:eu-repo/semantics/closedAccess
op_doi https://doi.org/10.1256/qj.02.98
container_title Quarterly Journal of the Royal Meteorological Society
container_volume 129
container_issue 593
container_start_page 2495
op_container_end_page 2511
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