Lidar observations of large-amplitude mountain waves in the stratosphere above Tierra del Fuego, Argentina

Kaifler, Natalie; Kaifler, Bernd; Dörnbrack, Andreas; Rapp, Markus; Hormaechea, José Luis; Torre, A. de la

doi:10.1038/s41598-020-71443-7

Cited by 39 publications

(80 citation statements)

References 53 publications

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“…This structure is relatively unperturbed by topographically forced planetary wave activity, unlike in the NH. These factors provide ideal conditions for the propagation of mountain waves into the stratosphere and higher during winter (e.g., Kaifler et al., 2020; Liu et al., 2019).…”

Section: Resultsmentioning

confidence: 99%

An 18‐Year Climatology of Directional Stratospheric Gravity Wave Momentum Flux From 3‐D Satellite Observations

Hindley

Wright

Hoffmann

et al. 2020

Geophysical Research Letters

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Atmospheric gravity waves (GWs) are key drivers of the atmospheric circulation, but their representation in general circulation models (GCMs) is challenging, leading to significant biases in middle atmospheric circulations. Unresolved GW momentum transport in GCMs must be parameterized, but global directional GW observations are needed to constrain this. Here we present an 18-year climatology of directional stratospheric GW momentum flux (GWMF) from global AIRS/Aqua 3-D satellite observations during 2002 to 2019. Striking hemispheric asymmetries are found at high latitudes, including dramatic reductions and reversals of GWMF during sudden stratospheric warmings. During Southern Hemisphere winter, a lateral convergence of GWMF toward 60°S is found that has no Northern Hemisphere counterpart. In the tropics, we find that zonal GWMF in AIRS measurements is strongly modulated by the semiannual oscillation (SAO) but not the quasi-biennial oscillation (QBO). Our results provide guidance for future GW parameterizations needed to resolve long-standing biases in GCMs. Plain Language Summary Gravity waves (GWs) are traveling waves that can occur in geophysical fluid environments subject to the gravitational force. In the Earth's atmosphere, GWs transport momentum that helps to drive the atmospheric circulation, especially in the middle atmosphere. But for numerical weather and climate models, accurately simulating GWs has proven very challenging because of a lack of GW observations, leading to significant model biases. Here we present an 18-year climatology of GW observations near 40-km altitude for 2002 to 2019. For the first time, we present multidecadal global measurements of directional GW momentum flux derived from 3-D satellite observations from National Aeronautics and Space Administration's (NASA's) AIRS instrument. We find that during Southern Hemisphere winter, GWs travel laterally toward 60°S each year. This is significant because most models underestimate GW momentum near 60°S and do not typically include lateral propagation in their parameterizations. In the tropical stratosphere, we find no modulation of GWs in AIRS observations by the quasi-biennial oscillation (QBO). This is consistent with the hypothesis that GW-QBO interactions occur at shorter vertical wavelengths, which are invisible to AIRS. Our results will help to guide future GW parameterizations, leading to more accurate atmospheric simulations and ultimately better forecasts of weather and climate.

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Section: Resultsmentioning

confidence: 99%

An 18‐Year Climatology of Directional Stratospheric Gravity Wave Momentum Flux From 3‐D Satellite Observations

Hindley

Wright

Hoffmann

et al. 2020

Geophysical Research Letters

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“…The Estación Astrónomicas Río Grande (EARG) which is located close to the airport of Rio short-term weather forecasts of clouds and precipitation. CORAL lidar data was used to study a long-term, large-amplitude stratospheric mountain wave event, and was combined with another lidar and satellite data to spatially resolve the structure of a GW (Kaifler et al 2020;Alexander et al 2020).…”

Section: B Ground-based and Satellite Instruments And Radiosondesmentioning

confidence: 99%

SOUTHTRAC-GW: An Airborne Field Campaign to Explore Gravity Wave Dynamics at the World’s Strongest Hotspot

Rapp

Kaifler

Dörnbrack

et al. 2021

Bulletin of the American Meteorological Society

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“…These parameters were chosen to be representative of a GW packet arising from a strong lower atmosphere source of high‐frequency GWs such as mountain waves (MWs) arising over the Southern Andes. Recent lidar observations over Rio Grande Tierra del Fuego (53.8°S) well in the lee and south of the major peaks reveal MWs with amplitudes often of

T^{'}

∼30 K near and below ∼40 km, implying

u^{'} \sim (g / N) T^{'} / T_{0} \sim 65

m / s

(Kaifler et al., 2020). GW imaging at ∼87 km and radar wind measurements from ∼80–100 km also reveal that under suitable propagation conditions, these MWs readily penetrate well into the MLT (D. Pautet and K. limura, private communications, 2017).…”

Section: Cgcam‐pmc Modelmentioning

confidence: 99%

Modeling Responses of Polar Mesospheric Clouds to Gravity Wave and Instability Dynamics and Induced Large‐Scale Motions

et al. 2021

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A gravity wave (GW) model that includes influences of temperature variations and large‐scale advection on polar mesospheric cloud (PMC) brightness having variable dependence on particle radius is developed. This Complex Geometry Compressible Atmosphere Model for PMCs (CGCAM‐PMC) is described and applied here for three‐dimensional (3‐D) GW packets undergoing self‐acceleration (SA) dynamics, breaking, momentum deposition, and secondary GW (SGW) generation below and at PMC altitudes. Results reveal that GW packets exhibiting strong SA and instability dynamics can induce significant PMC advection and large‐scale transport, and cause partial or total PMC sublimation. Responses modeled include PMC signatures of GW propagation and SA dynamics, “voids” having diameters of ∼500–1,200 km, and “fronts” with horizontal extents of ∼400–800 km. A number of these features closely resemble PMC imaging by the Cloud Imaging and Particle Size (CIPS) instrument aboard the Aeronomy of Ice in the Mesosphere (AIM) satellite. Specifically, initial CGCAM‐PMC results closely approximate various CIPS images of large voids surrounded by smaller void(s) for which dynamical explanations have not been offered to date. In these cases, the GW and instabilities dynamics of the initial GW packet are responsible for formation of the large void. The smaller void(s) at the trailing edge of a large void is (are) linked to the lower‐ or higher‐altitude SGW generation and primary mean‐flow forcing. We expect an important benefit of such modeling to be the ability to infer local forcing of the mesosphere and lower thermosphere (MLT) over significant depths when CGCAM‐PMC modeling is able to reasonably replicate PMC responses.

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Lidar observations of large-amplitude mountain waves in the stratosphere above Tierra del Fuego, Argentina

Cited by 39 publications

References 53 publications

An 18‐Year Climatology of Directional Stratospheric Gravity Wave Momentum Flux From 3‐D Satellite Observations

An 18‐Year Climatology of Directional Stratospheric Gravity Wave Momentum Flux From 3‐D Satellite Observations

SOUTHTRAC-GW: An Airborne Field Campaign to Explore Gravity Wave Dynamics at the World’s Strongest Hotspot

Modeling Responses of Polar Mesospheric Clouds to Gravity Wave and Instability Dynamics and Induced Large‐Scale Motions

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