A Brief Overview of Gravity Wave Retrieval Techniques From Observations

Sakib, Md Nazmus; Yiğit, Erdal

doi:10.3389/fspas.2022.824875

Cited by 6 publications

(6 citation statements)

References 83 publications

(106 reference statements)

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“…The full 7 years worth of NGIMS density observations could be employed in a future study to try to better optimize the GW scheme within the model under different conditions. In general, it is challenging to validate modeled gravity wave activity with respect to observations, since there are a number of different gravity wave retrieval techniques and they can yield different results depending on how the background fields are determined (Sakib & Yiğit, 2022). One of the challenges that remains in using a GW parameterization scheme is that the source GW spectrum is still not well known at Mars, but is likely more complex than the Gaussian used here and may be time-varying.…”

Section: Discussionmentioning

confidence: 99%

Impacts of Gravity Waves in the Martian Thermosphere: The Mars Global Ionosphere‐Thermosphere Model Coupled With a Whole Atmosphere Gravity Wave Scheme

et al. 2022

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Gravity waves are a key mechanism that facilitates coupling between the lower and upper atmosphere of Mars. In order to better understand the mean, large‐scale impacts of gravity waves on the thermosphere, a modern whole atmosphere, nonlinear, non‐orographic gravity wave parameterization scheme has been incorporated into a three‐dimensional ground‐to‐exosphere Mars general circulation model, the Mars Global Ionosphere‐Thermosphere Model (M‐GITM). M‐GITM simulations utilizing the gravity wave parameterization indicate that significant gravity wave momentum is deposited in the thermosphere, especially within the altitude range of 90–170 km. This impacts the winds in the thermosphere; in particular, M‐GITM simulations show a decrease in speed of the wind maximum in the summer hemisphere by over a factor of two. Gravity wave effects also impact the temperatures above 120 km in the model, producing a cooler simulated thermosphere at most latitudes. M‐GITM results were also compared to upper atmospheric temperature and wind data sets from the MAVEN (Mars Atmosphere and Volatile Evolution) spacecraft. Some aspects of wind data‐model comparisons improved once the gravity wave scheme was added to M‐GITM; furthermore, a cooler temperature profile produced by these new M‐GITM simulations for the MAVEN Deep Dip 2 observational campaign resulted in a closer data‐model comparison, particularly above 180 km. Overall, these modeling results show that gravity waves play an important role for the energy and momentum budget of the Martian thermosphere.

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Section: Discussionmentioning

confidence: 99%

Impacts of Gravity Waves in the Martian Thermosphere: The Mars Global Ionosphere‐Thermosphere Model Coupled With a Whole Atmosphere Gravity Wave Scheme

et al. 2022

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Section: Resultsmentioning

confidence: 99%

“…Besides, no matter what background trend is removed, the wave signal in the residue profile only becomes significant for altitudes above 60 km. More details on the evaluation of different extraction methods of GWs can be found in the review by Sakib and Yiğit (2022). The structure of temperature perturbations δT can be fitted by GWs with multiple vertical wavelengths:…”

Section: Analysis and Fitting Of The Observed Wavesmentioning

confidence: 99%

“…Such procedure has been widely used in Earth's and Mars's atmosphere. There are also reviews and studies evaluating different methods to fit the background T, such as spectral filtering, moving average, and polynomial fit (John & Kumar, 2013;Sakib & Yiğit, 2022;Starichenko et al, 2021;Wu et al, 2022). Lorenz et al (2014) calculated a background trend by taking the moving average over the original observations with a window of 41 data points (around 10 km in altitude).…”

Section: Analysis and Fitting Of The Observed Wavesmentioning

confidence: 99%

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The Propagation of Gravity Waves in Titan's Stratosphere

Huang

Shao

et al. 2023

JGR Planets

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Titan has a dense atmosphere that is primarily made up of N 2 and CH 4 (Cui et al., 2009;Magee et al., 2009;Vervack et al., 2004) and possesses a complicated thermal structure (Koskinen et al., 2011). Previous research has identified distinct troposphere, stratosphere, mesosphere, and thermosphere in Titan's atmosphere (Yelle, 1991;Yelle et al., 1997). Titan's atmosphere is more extended than Earth's because of its lower surface gravity and high surface pressure, and its atmospheric layers cover larger altitude scales. Titan's troposphere has a negative temperature gradient and extends up to 40 km. The stratosphere extends from the tropopause to around 300 km and has a positive temperature gradient due to the haze's absorption of solar radiation. The mesosphere has a negative temperature gradient due to HCN cooling and reaches up to 400 km. The thermosphere, which is above these, has a positive temperature gradient caused by solar EUV heating (Lorenz, 2014;Müller-Wodarg et al., 2014). As the Huygens probe arrives and descends on Titan, we now have an in situ observation of temperature profile for Titan's atmosphere. Previous studies have discovered wave-like temperature perturbations in this temperature profile and explained them as gravity waves (GWs) (

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“…The coordinates of Equation 1 refer to the geometry of the MATS tomography output, where x refers to the along-track distance, y the across-track distance, z the height and t the time. Different methods for background removal have been discussed by Sakib and Yigit (2022). The separation of scales is typically made based on research interests and/or measurement limitations.…”

Section: Introductionmentioning

confidence: 99%

Scale separation for gravity wave analysis from 3D temperature observations in the MLT region

Linder,

Preusse,

Chen

et al. 2024

Preprint

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Abstract. MATS (Mesospheric Airglow/Aerosol, Tomography & Spectroscopy) is a Swedish satellite designed to investigate atmospheric dynamics in the Mesosphere and Lower Thermosphere (MLT). From observing structures in noctilucent clouds over polar regions, and oxygen A-band emissions globally, MATS will supply the research community with properties of the MLT atmospheric wave field. Individual A-band images taken by the MATS main instrument, a 6-channel limb imager, are through tomography and spectroscopy turned into three-dimensional temperature fields in which the wave structures are embedded. To identify wave properties, in particular the gravity wave momentum flux, from the temperature field, smaller-scale perturbations, associated with the targeted waves, must be separated from large-scale background variations by a method of scale separation. This paper investigates the possibilities of employing a simple method based on smoothing polynomials to separate the smaller and larger scales. By using synthetic tomography data based on the HIAMCM (High Altitude Mechanistic Circulation Model) we demonstrate that smoothing polynomials can be applied to MLT temperatures to obtain fields corresponding to a global scale separation at zonal wavenumber 18. The simplicity of the method makes it a promising candidate for studying wave dynamics in the MATS temperature fields.

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A Brief Overview of Gravity Wave Retrieval Techniques From Observations

Cited by 6 publications

References 83 publications

Impacts of Gravity Waves in the Martian Thermosphere: The Mars Global Ionosphere‐Thermosphere Model Coupled With a Whole Atmosphere Gravity Wave Scheme

Impacts of Gravity Waves in the Martian Thermosphere: The Mars Global Ionosphere‐Thermosphere Model Coupled With a Whole Atmosphere Gravity Wave Scheme

The Propagation of Gravity Waves in Titan's Stratosphere

Scale separation for gravity wave analysis from 3D temperature observations in the MLT region

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