91̽��

Abstract:

This dataset comprises time-resolved, two-component horizontal velocity fields from experiments in a rotating, differentially heated fluid annulus. The experiments were conducted at the GFDLab, 91̽��.

Abstract:

Barotropic instability represents a class of instabilities, usually of parallel shear flows, for which gravity and buoyancy play a negligible role, at least in their energetics. It is not restricted to purely barotropic fluids (for which ����=����(p), where �� is density and p is pressure) but can also apply to flows which are stratified and exhibit vertical shear, often leading to instabilities with mixed barotropic and baroclinic characteristics. The primary attribute of barotropic instability is usually taken to be the dominance of energy exchanges in which the kinetic energy of a perturbation grows principally at the expense of the kinetic energy of the basic state. Here we present an introduction to the basic mechanisms involved and the factors that determine the necessary and/or sufficient conditions for instability. Several examples are presented and the occurrence and subsequent nonlinear evolution of the instability is illustrated with reference to both laboratory experiments and observations in the atmospheres and oceans of the Earth and other planets in the Solar System.

Abstract:

Recent analyses of wind measurements obtained from tracking cloud motions in spacecraft images of Jupiter and Saturn[1,2] indicate that nonlinear scale-to-scale transfers of kinetic energy act from small to large scales over a wide range of length scales, much as anticipated for 2D or geostrophic turbulence paradigms. At the smallest resolvable scales, however, there is evidence in observations of a forward (downscale) transfer, at least at low and middle latitudes on Jupiter, much like in the Earth’s atmosphere. Moreover, the upscale transfers at the largest spatial scales are evidently dominated by spectrally non-local, highly anisotropic eddy-zonal interactions associated with the generation of intense zonal jets and equatorial super-rotation by direct eddy-zonal flow exchanges. Most analyses to date have emphasised the global mean interactions for both planets, thereby focusing on the spatially homogeneous and isotropic components of the turbulence. Here we present some new analyses of spectral energy transfers on both Jupiter and Saturn that resolve variations in latitude[cf 3], thereby shedding new light on non-homogeneous aspects of jovian turbulent interactions. The results indicate significant variability and inhomogeneity between different locations, with a clear distinction between the tropics, the extratropical middle latitudes and the polar regions. We discuss these in light of other observations and models of gas giant circulation and related laboratory experimental analogues.[1] Antu˜nano, A., del Río-Gaztelurrutia, T., Sánchez-Lavega, A., & Hueso, R. (2015) Dynamics of Saturn’s polar regions. J. Geophys. Res.: Planets, 120 , 155–176. doi:10.1002/2014JE004709[2] Read, P. L., Antu˜nano, A., Cabanes, S., Colyer, G., del Río-Gaztelurrutia, T., Sánchez-Lavega, A. (2022). Energy exchanges in Saturn’s polar regions fromCassini observations: Eddy-zonal flow interactions. J. Geophys. Res., 127 , e2021JE006973. https://doi.org/10.1029/2021JE006973[3] Chemke, R., & Kaspi, Y. (2015). The latitudinal dependence of atmospheric jet scales and macroturbulent energy cascades. J. Atmos. Sci., 72 , 3891–3907. doi: 10.1175/JAS-D-15-0007.

Abstract:

Recent studies of the climate and weather on Mars have benefitted greatly from the development of publicly available “reanalysis” datasets. These are quantitative reconstructions of the three-dimensional, multivariate, time-varying state of the Martian atmosphere, obtained by combining observations of atmospheric variables, usually from remote sensing platforms in orbit around the planet, with a numerical model simulation of the entire atmospheric circulation and surface, using a statistical-dynamical algorithm known as an “assimilation”. The result represents an estimate of the evolving state of the entire global weather and climate that makes optimal use of both direct observations and physical knowledge of the physics and chemistry of the atmosphere and surface (as contained in the design of the numerical model), taking into account statistical uncertainties in both measurements and model simulations. This approach thereby takes account of measurement uncertainty, the incomplete coverage of observations in both space and time and enables the estimation of variables that cannot be measured directly through the internal dynamical consistency of the numerical model. At least four such datasets have been produced during the past decade or so [1-6], based on recent spacecraft observations from the Thermal Emission Spectrometer (TES) on NASA’s Mars Global Surveyor (MGS), the Mars Climate Sounder (MCS) instrument on NASA’s Mars Reconnaissance Orbiter (MRO), the Atmospheric Chemistry Suite thermal infrared channel (ACS-TIRVIM) on ESA's Trace Gas Orbiter and the Emirates Mars InfraRed Spectrometer (EMIRS) on the Emirates Mars Mission (EMM), using different assimilation algorithms. In most cases so far, the data assimilated has been limited to retrieved surface temperature and atmospheric temperature profiles, together with column integrated dust opacities (CIDO) and certain other trace gases. Although this leads to reasonable agreement between different assimilations and with independent, out of sample measurements, the neglect of measurements of the vertical structure of atmospheric dust loading leads to significant errors in modelled radiative heating and cooling rates that temperature assimilation is then required to correct. Such a correction is highly undesirable, quite apart from misrepresenting the structure and transport of dust aerosol by the circulation, and increases the likelihood of systematic errors in the reconstructed circulation. In recent work [4], the Analysis Correction system used for the Mars Analysis Correction Assimilation (MACDA) reanalysis [1] has been extended to enable the assimilation of both CIDO and profiles of dust opacity obtained from limb-sounding instruments such as MCS. The results have enabled phenomena such as the climatological elevated dust layers during northern hemisphere summer to be captured in a reanalysis (see Fig. 1), which has been elusive in previous work. In new work presented here, this approach has now been applied to more than 12 Mars years of observations, from early MY24 to the beginning of MY36 (to date), based mainly on retrievals of temperature and dust opacity from the MGS/TES and MRO/MCS instruments that have been assimilated into the UK version of the LMD Mars Planetary Climate Model. This dataset will shortly be available publicly via the UK Centre for Environmental Data Analysis (https://www.ceda.ac.uk/). Here we present an overview of the new reanalysis and illustrate some of its results with the aim of alerting researchers to this new resource for future studies. PLR and AV acknowledge 91̽�� from the UK Space Agency. The authors are grateful to Armin Kleinböhl and the MCS science team for advice and early access to retrieved data.Figure 1: Snapshots of the zonally averaged structure of the Martian atmosphere during northern late summer in Mars Year 28, showing the zonal and vertical wind, temperature and dust distribution, showing the presence of a persistent elevated dust layer from the MACDA2 reanalysis.[1] Montabone, L., Marsh, K., Lewis, S. R., Read, P. L., Smith, M. D., Holmes, J., et al. (2014). The Mars Analysis Correction Data Assimilation (MACDA) dataset V1.0. Geoscience Data Journal, 1(2), 129–139. https://doi.org/10.1002/gdj3.13[2] Greybush, S. J., Kalnay, E., Wilson, R. J., Hoffman, R. N., Nehrkorn, T., Leidner, M., et al. (2019). The Ensemble Mars Atmosphere Reanalysis System (EMARS) version 1.0. Geoscience Data Journal, 6(2), 137–150. https://doi.org/10.1002/gdj3.77[3] Holmes, J. A., Lewis, S. R., & Patel, M. R. (2020). OpenMARS: A global record of Martian weather from 1999 to 2015. Planetary and Space Science, 188, 104962. https://doi.org/10.1016/j.pss.2020.104962[4] Ruan, T., Young, R. M. B., Lewis, S. R., Montabone, L., Valeanu, A., & Read, P. L. (2021). Assimilation of both column- and layer-integrated dust opacity observations in the Martian atmosphere. Earth and Space Science, 8(12), e2021EA001869. https://doi.org/10.1029/2021EA001869[5] Young, R. M. B., Millour, E., Guerlet, S., Forget, F., Ignatiev, N., Grigoriev, A. V., et al. (2022). Assimilation of temperatures and column dust opacities measured by ExoMars TGO-ACS-TIRVIM during the MY34 Global Dust Storm. Journal of Geophysical Research: Planets, 127, e2022JE007312. https://doi.org/10.1029/2022JE007312[6] Young, R. M. B., Millour, E., Forget, F., Smith, M. D., Aljaberi, M., Edwards, C. S., et al. (2022). First assimilation of atmospheric temperatures from the Emirates Mars InfraRed Spectrometer. Geophysical Research Letters, 49, e2022GL099656.