Abstract

Abstract. We analysed 286 nights of data from the OH* airglow imager FAIM 3 (Fast Airglow IMager) acquired at Otlica Observatory (45.93∘ N, 13.91∘ E), Slovenia, between 26 October 2017 and 6 June 2019. Measurements have been performed with a spatial resolution of 24 m per pixel and a temporal resolution of 2.8 s. A two-dimensional fast Fourier transform is applied to the image data to derive horizontal wavelengths between 48 m and 4.5 km in the upper mesosphere/lower thermosphere (UMLT) region. In contrast to the statistics of larger-scale gravity waves (horizontal wavelength up to ca. 50 km; Hannawald et al., 2019), we find a more isotropic distribution of directions of propagation, pointing to the presence of wave structures created above the stratospheric wind fields. A weak seasonal tendency of a majority of waves propagating eastward during winter may be due to instability features from breaking secondary gravity waves that were created in the stratosphere. We also observe an increased southward propagation during summer, which we interpret as an enhanced contribution of secondary gravity waves created as a consequence of primary wave filtering by the meridional mesospheric circulation. We present multiple observations of turbulence episodes captured by our high-resolution airglow imager and estimated the energy dissipation rate in the UMLT from image sequences in 25 cases. Values range around 0.08 and 9.03 W kg−1 and are on average higher than those in recent literature. The values found here would lead to an approximated localized maximum heating of 0.03–3.02 K per turbulence event. These are in the same range as the daily chemical heating rates for the entire atmosphere reported by Marsh (2011), which apparently stresses the importance of dynamical energy conversion in the UMLT.

Highlights

  • Understanding the contribution of gravity waves to atmospheric dynamics is still a major issue when establishing climate models

  • We present an analysis of small-scale dynamics of instability features and turbulence from OH* imager data acquired between 26 October 2017 and 6 June 2019 at Otlica Observatory, Slovenia

  • Measurements have been performed with the imager FAIM 3, which has a spatial resolution of ca. 24 m per pixel and a temporal resolution of 2.8 s

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Summary

Introduction

Understanding the contribution of gravity waves to atmospheric dynamics is still a major issue when establishing climate models. Due to the various sources and mechanisms of interactions, the effects of gravity waves have to be represented in these models using advanced parameterizations (Lindzen, 1981; Holton, 1983; de la Cámara et al, 2016) to cover as many aspects as is possible given the restricted model resolution. 4–5 min in the upper mesosphere/lower thermosphere (UMLT) region (Wüst et al, 2017b) and represents the smallest possible period of gravity waves. They show diverse behaviour depending strongly on wave properties like their periodicity (Fritts and Alexander, 2003; Beldon and Mitchell, 2009; Hoffmann et al, 2010; Wüst et al, 2016; Sedlak et al, 2020), which makes it even harder to fully account for them by means of parameterization. Gravity wave generation is not restricted to the troposphere but can take place at higher altitudes, such as secondary wave excitation due to breaking gravity waves (see, for example, Holton and Alexander, 1999; Satomura and Sato, 1999; Vadas and Fritts, 2001; Becker and Vadas, 2018).

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