Stratospheric Trailing Gravity Waves from New Zealand

Gravity waves are frequently observed in the stratosphere, trailing long distances from mid- to high-latitude topography. Two such trailing-wave events documented over New Zealand are examined using observations, numerical simulations, and ray-tracing analysis to explore and document stratospheric t...

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Published in	Journal of the atmospheric sciences Vol. 76; no. 6; pp. 1565 - 1586
Main Authors	Jiang, Qingfang, Doyle, James D., Eckermann, Stephen D., Williams, Bifford P.
Format	Journal Article
Language	English
Published	Boston American Meteorological Society 01.06.2019
Subjects	Absorption Computer simulation Data assimilation Energy distribution Gravitational waves Gravity Gravity waves Horizontal distribution Numerical simulations Orientation Orographic gravity waves Perturbation Refraction Simulation Stratosphere Terrain Topography Wave propagation Wave refraction Wavelength Weather forecasting Westerlies Wind Wind shear Winds New Zealand Antarctic Peninsula Southern Ocean
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Abstract	Gravity waves are frequently observed in the stratosphere, trailing long distances from mid- to high-latitude topography. Two such trailing-wave events documented over New Zealand are examined using observations, numerical simulations, and ray-tracing analysis to explore and document stratospheric trailing-wave characteristics and formation mechanisms. We find that the trailing waves over New Zealand are orographically generated and regulated by several processes, including interaction between terrain and mountaintop winds, critical-level absorption, and lateral wave refraction. Among these, the interaction between topography and low-level winds determines the perturbation energy distribution over horizontal scales and directions near the wave source, and accordingly, trailing waves are sensitive to terrain features and low-level winds. Terrain-forced wave modes are filtered by absorption associated with directional wind shear and Jones critical levels. The former plays a role in defining wave-beam orientation, and the latter sets an upper limit for the permissible horizontal wavelength of trailing waves. On propagating into the stratosphere, these orographic gravity waves are subject to horizontal refraction associated with the meridional shear in the stratospheric westerlies, which tends to elongate the wave beams pointing toward stronger westerlies and shorten the wave beams on the opposite side.
AbstractList	Gravity waves are frequently observed in the stratosphere, trailing long distances from mid- to high-latitude topography. Two such trailing-wave events documented over New Zealand are examined using observations, numerical simulations, and ray-tracing analysis to explore and document stratospheric trailing-wave characteristics and formation mechanisms. We find that the trailing waves over New Zealand are orographically generated and regulated by several processes, including interaction between terrain and mountaintop winds, critical-level absorption, and lateral wave refraction. Among these, the interaction between topography and low-level winds determines the perturbation energy distribution over horizontal scales and directions near the wave source, and accordingly, trailing waves are sensitive to terrain features and low-level winds. Terrain-forced wave modes are filtered by absorption associated with directional wind shear and Jones critical levels. The former plays a role in defining wave-beam orientation, and the latter sets an upper limit for the permissible horizontal wavelength of trailing waves. On propagating into the stratosphere, these orographic gravity waves are subject to horizontal refraction associated with the meridional shear in the stratospheric westerlies, which tends to elongate the wave beams pointing toward stronger westerlies and shorten the wave beams on the opposite side.
Author	Williams, Bifford P. Jiang, Qingfang Eckermann, Stephen D. Doyle, James D.
Author_xml	– sequence: 1 givenname: Qingfang surname: Jiang fullname: Jiang, Qingfang organization: Marine Meteorology Division, U.S. Naval Research Laboratory, Monterey, California – sequence: 2 givenname: James D. surname: Doyle fullname: Doyle, James D. organization: Marine Meteorology Division, U.S. Naval Research Laboratory, Monterey, California – sequence: 3 givenname: Stephen D. surname: Eckermann fullname: Eckermann, Stephen D. organization: Space Science Division, U.S. Naval Research Laboratory, Washington, D.C – sequence: 4 givenname: Bifford P. surname: Williams fullname: Williams, Bifford P. organization: Boulder Division, GATS, Boulder, Colorado
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Snippet	Gravity waves are frequently observed in the stratosphere, trailing long distances from mid- to high-latitude topography. Two such trailing-wave events...
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SubjectTerms	Absorption Computer simulation Data assimilation Energy distribution Gravitational waves Gravity Gravity waves Horizontal distribution Numerical simulations Orientation Orographic gravity waves Perturbation Refraction Simulation Stratosphere Terrain Topography Wave propagation Wave refraction Wavelength Weather forecasting Westerlies Wind Wind shear Winds
Title	Stratospheric Trailing Gravity Waves from New Zealand
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