Assimilation of atmospheric infrasound data to constrain tropospheric and stratospheric winds

Amezcua, Javier; Näsholm, Sven Peter; Blixt, E. M.; Charlton‐Perez, Andrew

doi:10.1002/qj.3809

Cited by 14 publications

(21 citation statements)

References 64 publications

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“…Resolving small-scale structures in atmospheric models, reanalysis, and forecasting systems remains a topic of active research. Several research efforts were made to develop methods exploiting infrasound observations to improve the representation of wind and temperature in atmospheric model products (e.g., Chunchuzov et al, 2015;Assink et al, 2019;Amezcua et al, 2020;Vera Rodriguez et al, 2020).…”

Section: Discussionmentioning

confidence: 99%

“…These limitations have been accordingly raised in the context of microbaroms (Landès et al, 2014). Therefore, in this study, the parametrization used to run the WWIII model accounts for fixed reflection coefficients of 10 % for the continents, 20 % for the islands, and 40 % for ice sheets (Ardhuin et al, 2011). Microbarom source model.…”

Section: Microbarom Source and Propagation Modelingmentioning

confidence: 99%

“…The low-frequency microbaroms can be ducted over long distances due to the weak attenuation, which is proportional to the frequency squared. Hence, there is a potential to exploit microbaroms to probe the dynamics of the stratosphere, where the representation of the atmospheric dynamics in model products is often poorly constrained (Polavarapu et al, 2005;Rienecker et al, 2011;Smith, 2012;Amezcua et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

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Benchmarking microbarom radiation and propagation model against infrasound recordings: a vespagram-based approach

et al. 2021

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Abstract. This study investigates the use of a vespagram-based approach as a tool for multi-directional comparison between simulated microbarom soundscapes and infrasound data recorded at ground-based array stations. Data recorded at the IS37 station in northern Norway during 2014–2019 have been processed to generate vespagrams (velocity spectral analysis) for five frequency bands between 0.1 and 0.6 Hz. The back azimuth resolution between the vespagram and the microbarom model is harmonized by smoothing the modeled soundscapes along the back azimuth axis with a kernel corresponding to the frequency-dependent array resolution. An estimate of similarity between the output of the microbarom radiation and propagation model and infrasound observations is then generated based on the image-processing approach of the mean square difference. The analysis reveals that vespagrams can monitor seasonal variations in the microbarom azimuthal distribution, amplitude, and frequency, as well as changes during sudden stratospheric warming events. The vespagram-based approach is computationally inexpensive, can uncover microbarom source variability, and has the potential for near-real-time stratospheric diagnostics and atmospheric model assessment.

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Section: Discussionmentioning

confidence: 99%

Section: Microbarom Source and Propagation Modelingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Benchmarking microbarom radiation and propagation model against infrasound recordings: a vespagram-based approach

et al. 2021

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“…As microbaroms propagate into the middle atmosphere (from around 12 to 90 km altitude), significant features of the vertical structure of the temperature and wind are reflected in the detected signal on the ground. The lack of variability found in both temperature and wind models (e.g., Charlton‐Perez et al., 2013; Lee et al., 2019) has motivated the development of atmospheric remote sensing methods for evaluating numerical weather prediction (NWP) model output (e.g., Amezcua et al., 2020; Le Pichon et al., 2015; Vanderbecken et al., 2020). With the increasing number of IMS stations complemented by dense regional networks, systematic studies using historical infrasound data sets and state‐of‐the‐art (re)analysis systems provide useful integrated information on middle atmosphere variability and biases where data coverage is sparse (Blanc et al., 2019).…”

Section: Introductionmentioning

confidence: 99%

Global Microbarom Patterns: A First Confirmation of the Theory for Source and Propagation

Carlo

Hupe

Pichon

et al. 2021

Geophysical Research Letters

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Microbarom signals are generated by wind waves at the ocean surface and propagate all around the globe through the stratosphere and ionosphere. Microbaroms dominate the coherent infrasound ambient noise measured worldwide, with a peak around 0.2 Hz. Monitoring these signals allows characterizing the source activity and probing the properties of their propagation medium, the middle atmosphere. Here, we show the first quantitative validation of global microbarom modeling based on ocean wave models, a new source model and atmospheric attenuation. For evaluating these parameters' impact, we compare the modeling results with a global reference database of microbaroms detected by the infrasound International Monitoring System over 7 years. This study demonstrates that the new source model improves the prediction rate of observations by around 20% points against previous models. The performance is enhanced when the new model is combined with a wind‐dependent attenuation and an ocean wave model that includes coastal reflection.

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“…Because of the low frequencies, microbaroms can penetrate the middle atmosphere and return back to ground at long ranges. Hence there is potential to exploit this source to probe the dynamics of this altitude range, where the representation of the atmospheric dynamics in model products is often poorly constrained (Polavarapu et al, 2005;Rienecker et al, 2011;Smith, 2012;Amezcua et al, 2020). 1 https://doi.org/10.5194/angeo-2020-78 Preprint.…”

Section: Introductionmentioning

confidence: 99%

Microbarom radiation and propagation model assessment using infrasound recordings: a vespagram-based approach

Vorobeva

Carlo

Pichon

et al. 2020

Preprint

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Abstract. This study investigates the use of a vespagram-based approach as a tool for multi-directional comparison between simulated microbarom soundscapes and infrasound data recorded at ground-based array stations. Data recorded at the IS37 station in northern Norway during 2014–2019 have been processed to generate vespagrams (velocity spectral analysis) for five frequency bands between 0.1 and 0.6 Hz. The back-azimuth resolution between vespagrams and a microbarom model is harmonized by smoothing the modelled soundscapes along the back-azimuth axis with a kernel corresponding to the frequency-dependent array resolution. An estimate of similarity between the output of a microbarom radiation and propagation model and infrasound observations is then generated based on the image processing approach of mean-square difference. The analysis revealed that vespagrams can monitor seasonal variations in the microbarom azimuth distribution, amplitude, and frequency, as well as changes during sudden stratospheric warming. The vespagram-based approach is computationally inexpensive, can uncover microbarom source variability, and has potential for near-real-time stratospheric diagnostics and atmospheric model assessment.

show abstract

Assimilation of atmospheric infrasound data to constrain tropospheric and stratospheric winds

Cited by 14 publications

References 64 publications

Benchmarking microbarom radiation and propagation model against infrasound recordings: a vespagram-based approach

Benchmarking microbarom radiation and propagation model against infrasound recordings: a vespagram-based approach

Global Microbarom Patterns: A First Confirmation of the Theory for Source and Propagation

Microbarom radiation and propagation model assessment using infrasound recordings: a vespagram-based approach

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