Can Quasi‐Periodic Gravity Waves Influence the Shape of Ice Crystals in Cirrus Clouds?

Saha, Sourita; Kumar, Kondapalli Niranjan; Sharma, Som; Kumar, Prashant; Joshi, Vaidehi

doi:10.1029/2020gl087909

Cited by 8 publications

(3 citation statements)

References 56 publications

(78 reference statements)

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“…As discussed by Strube et al (2020), below 20 km altitude zonal wavenumbers of 10 and higher need to be taken into account to describe the background. These cannot be self-consistently estimated from a single-track low-Earth-orbit satellite (Salby and Callaghan, 1997). In order to isolate the small-scale GW contributions, ERA5 background data with an altitude-dependent zonal wavenumber cutoff have been subtracted from the retrieved HIRDLS temperature measurements.…”

Section: Hirdls Satellite Datamentioning

confidence: 99%

A mountain ridge model for quantifying oblique mountain wave propagation and distribution

Rhode¹,

Preusse²,

Ern³

et al. 2023

Atmos. Chem. Phys.

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Abstract. Following the current understanding of gravity waves (GWs) and especially mountain waves (MWs), they have a high potential for horizontal propagation from their source. This horizontal propagation and therefore the transport of energy is usually not well represented in MW parameterizations of numerical weather prediction and general circulation models. In this study, we present a mountain wave model (MWM) for the quantification of horizontal propagation of orographic gravity waves. This model determines MW source locations from topography data and estimates MW parameters from a fit of idealized Gaussian-shaped mountains to the elevation. Propagation and refraction of these MWs in the atmosphere are modeled using the Gravity-wave Regional Or Global Ray Tracer (GROGRAT). Ray tracing of each MW individually allows for an estimation of momentum transport due to both vertical and horizontal propagation. The MWM is a capable tool for the analysis of MW propagation and global MW activity and can support the understanding of observations and improvement of MW parameterizations in GCMs. This study presents the model itself and gives validations of MW-induced temperature perturbations to ECMWF Integrated Forecast System (IFS) numerical weather prediction data and estimations of GW momentum flux (GWMF) compared to HIgh Resolution Dynamics Limb Sounder (HIRDLS) satellite observations. The MWM is capable of reproducing the general features and amplitudes of both of these data sets and, in addition, is used to explain some observational features by investigating MW parameters along their trajectories.

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Section: Hirdls Satellite Datamentioning

confidence: 99%

A mountain ridge model for quantifying oblique mountain wave propagation and distribution

Rhode¹,

Preusse²,

Ern³

et al. 2023

Atmos. Chem. Phys.

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“…In their study, 20 Calleja et al obtained response solutions (i.e., quasi-periodic solutions with the same frequency as the forcing) of several models of nonlinear wave equations with very strong damping, such as 1 𝜖 u t for 𝜖 small enough. Recently, Saha et al 21 treated the influence of quasi-periodic gravity waves in the shape of crystals in clouds. Berti and Montalto 22 proved the existence of small amplitude quasi-periodic standing wave solutions of an ocean with infinite depth under the action of gravity and surface tension.…”

Section: Backgrounds and Main Ideasmentioning

confidence: 99%

Quasi‐periodic traveling waves for a class of damped beams on rectangular tori

Chen

Gao

Nieto

2021

Math Methods in App Sciences

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This article concerns a class of beam equations with damping on rectangular tori. When the generators satisfy certain relationship, by excluding some values of two model parameters, we prove that such models admit small amplitude quasi-periodic traveling wave solutions with two frequencies, which are continuations of two rotating wave solutions with one frequency. The result holds not only for a rational torus but also for an irrational one. The proof is mainly based on a Lyapunov-Schmidt reduction together with the implicit function theorem.

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“…In [6], Calleja et al obtained response solutions (i.e., quasi-periodic solutions with the same frequency as the forcing) of several models of nonlinear wave equations with very strong damping, such as 1 ǫ u t for ǫ small enough. Recently, Saha et al [24] treated the influence of quasi-periodic gravity waves in the shape of crystals in clouds. Berti-Montalto [2] proved the existence of small amplitude quasi-periodic standing wave solutions of an ocean with infinite depth under the action of gravity and surface tension.…”

Section: Introductionmentioning

confidence: 99%

Quasi-periodic travelling waves for a class of damped beams on rectangular tori

Chen,

Gao,

Nieto

2020

Preprint

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This article concerns a class of beam equations with damping on rectangular tori. When the generators satisfy certain relationship, by excluding some value of two model parameters, we prove that such models admit small amplitude quasi-periodic travelling wave solutions with two frequencies, which are continuations of two rotating wave solutions with one frequency. This result holds not only for an isotropic torus, but also for an anisotropic torus. The proof is mainly based on a Lyapunov-Schmidt reduction together with the implicit function theorem.

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Can Quasi‐Periodic Gravity Waves Influence the Shape of Ice Crystals in Cirrus Clouds?

Cited by 8 publications

References 56 publications

A mountain ridge model for quantifying oblique mountain wave propagation and distribution

A mountain ridge model for quantifying oblique mountain wave propagation and distribution

Quasi‐periodic traveling waves for a class of damped beams on rectangular tori

Quasi-periodic travelling waves for a class of damped beams on rectangular tori

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