More Like this

1. Revisiting the Quasi-Biennial Oscillation as Seen in ERA5. Part I: Description and Momentum Budget

   https://doi.org/10.1175/JAS-D-20-0248.1  

   Pahlavan, Hamid A.; Fu, Qiang; Wallace, John M.; Kiladis, George N. (March 2021, Journal of the Atmospheric Sciences)

   null (Ed.)

   Abstract The dynamics and momentum budget of the quasi-biennial oscillation (QBO) are examined in ERA5. Because of ERA5’s higher spatial resolution compared to its predecessors, it is capable of resolving a broader spectrum of atmospheric waves and allows for a better representation of the wave–mean flow interactions, both of which are of crucial importance for QBO studies. It is shown that the QBO-induced mean meridional circulation, which is mainly confined to the winter hemisphere, is strong enough to interrupt the tropical upwelling during the descent of the westerly shear zones. Since the momentum advection tends to damp the QBO, the wave forcing is responsible for both the downward propagation and for the maintenance of the QBO. It is shown that half the required wave forcing is provided by resolved waves during the descent of both westerly and easterly regimes. Planetary-scale waves account for most of the resolved wave forcing of the descent of westerly shear zones and small-scale gravity (SSG) waves with wavelengths shorter than 2000 km account for the remainder. SSG waves account for most of the resolved forcing of the descent of the easterly shear zones. The representation of the mean fields in the QBO is very similar in ERA5 and ERA-Interim but the resolved wave forcing is substantially stronger in ERA5. The contributions of the various equatorially trapped wave modes to the QBO forcing are documented in Part II. 

   more » « less
2. Circumpolar Variations in the Chaotic Nature of Southern Ocean Eddy Dynamics

   https://doi.org/10.1029/2022JC018440  

   Hogg, Andrew McC.; Penduff, Thierry; Close, Sally E.; Dewar, William K.; Constantinou, Navid C.; Martínez‐Moreno, Josué (May 2022, Journal of Geophysical Research: Oceans)

   Abstract Circulation in the Southern Ocean is unique. The strong wind stress forcing and buoyancy fluxes, in concert with the lack of continental boundaries, conspire to drive the Antarctic Circumpolar Current replete with an intense eddy field. The effect of Southern Ocean eddies on the ocean circulation is significant—they modulate the momentum balance of the zonal flow, and the meridional transport of tracers and mass. The strength of the eddy field is controlled by a combination of forcing (primarily thought to be wind stress) and intrinsic, chaotic, variability associated with the turbulent flow field itself. Here, we present results from an eddy‐permitting ensemble of ocean model simulations to investigate the relative contribution of forced and intrinsic processes in governing the variability of Southern Ocean eddy kinetic energy. We find that variations of the eddy field are mostly random, even on longer (interannual) timescales. Where correlations between the wind stress forcing and the eddy field exist, these interactions are dominated by two distinct timescales—a fast baroclinic instability response; and a multi‐year process owing to feedback between bathymetry and the mean flow. These results suggest that understanding Southern Ocean eddy dynamics and its larger‐scale impacts requires an ensemble approach to eliminate intrinsic variability, and therefore may not yield robust conclusions from observations alone. 

   more » « less
3. Large-scale balances and asymptotic scaling behaviour in spherical dynamos

   https://doi.org/10.1093/gji/ggab274  

   Calkins, Michael A; Orvedahl, Ryan J; Featherstone, Nicholas A (July 2021, Geophysical Journal International)

   Summary The large-scale dynamics of convection-driven dynamos in a spherical shell, as relevant to the geodynamo, is analyzed with numerical simulation data and asymptotic theory. An attempt is made to determine the asymptotic size (with the small parameter being the Ekman number, Ek) of the forces, and the associated velocity and magnetic fields. In agreement with previous work, the leading order mean force balance is shown to be thermal wind (Coriolis, pressure gradient, buoyancy) in the meridional plane and Coriolis-Lorentz in the zonal direction. The Lorentz force is observed to be weaker than the mean buoyancy force across a range of Ek and thermal forcing; the relative difference in these forces appears to be O(Ek1/6) within the parameter space investigated. We find that the thermal wind balance requires that the mean zonal velocity scales as O(Ek−1/3), whereas the meridional circulation is asymptotically smaller by a factor of O(Ek1/6). The mean temperature equation shows a balance between thermal diffusion and the divergence of the convective heat flux, indicating the presence of a mean temperature length scale of size O(Ek1/6). Neither the mean nor the fluctuating magnetic field show a strong dependence on the Ekman number, though the simulation data shows evidence of a mean magnetic field length scale of size O(Ek1/6). A consequence of the asymptotic ordering of the forces is that Taylor’s constraint is satisfied to accuracy O(Ek1/6), despite the absence of a leading-order magnetostrophic balance. Further consequences of the force balance are discussed with respect to the large-scale flows thought to be important for the geodynamo. 

   more » « less
4. Buoyancy Forcing Dominates the Cross-Equatorial Ocean Heat Transport Response to Northern Hemisphere Extratropical Cooling

   https://doi.org/10.1175/JCLI-D-21-0950.1  

   Luongo, Matthew T.; Xie, Shang-Ping; Eisenman, Ian (October 2022, Journal of Climate)

   Abstract Cross-equatorial ocean heat transport (OHT) changes have been found to damp meridional shifts of the intertropical convergence zone (ITCZ) induced by hemispheric asymmetries in radiative forcing. Zonal-mean energy transport theories and idealized model simulations have suggested that these OHT changes occur primarily due to wind-driven changes in the Indo-Pacific’s shallow subtropical cells (STCs) and buoyancy-driven changes in the deep Atlantic meridional overturning circulation (AMOC). In this study we explore the partitioning between buoyancy and momentum forcing in the ocean’s response. We adjust the top-of-atmosphere solar forcing to cool the Northern Hemisphere (NH) extratropics in a novel set of comprehensive climate model simulations designed to isolate buoyancy-forced and momentum-forced changes. In this case of NH high-latitude forcing, we confirm that buoyancy-driven changes in the AMOC dominate in the Atlantic. However, in contrast with prior expectations, buoyancy-driven changes in the STCs are the primary driver of the heat transport changes in the Indo-Pacific. We find that buoyancy-forced Indo-Pacific STC changes transport nearly 4 times the amount of heat across the equator as the shallower wind-driven STC changes. This buoyancy-forced STC response arises from extratropical density perturbations that are amplified by the low cloud feedback and communicated to the tropics by the ventilated thermocline. While the ocean’s specific response is dependent on the forcing scheme, our results suggest that partitioning the ocean’s total response to energy perturbations into buoyancy and momentum forcing provides basin-specific insight into key aspects of how the ocean damps ITCZ migrations that previous zonal-mean frameworks omit. 

   more » « less
5. Monthly mean Eliassen-Palm fluxes and EP flux divergences for boreal winter months (Dec-Jan-Feb) from 1979 to 2020 using ERA5 data

   https://doi.org/10.5281/zenodo.10140775  

   Du, Wenyuan; Hitchman, Matthew (January 2023, Zenodo)

   The European Centre for Medium-range Weather Forecasting (ECMWF) Reanalysis v5 (ERA5) data set (1979 – 2020) is used in many climate studies.  The present monthly mean data set of Eliassen-Palm fluxes (EP fluxes) and EP flux divergences, was created from twice-daily gridded values of ERA5 winds and temperature on pressure surfaces and is intended to fill a gap in availability.   It is compatible for use with ERA5 monthly mean data.   The EP flux is a diagnostic tool for assessing wave propagation and wave-mean flow interaction. It is a vector representation for the propagation of synoptic and planetary Rossby wave activity in the meridional plane.  An upward component indicates a poleward heat flux while an equatorward component indicates a poleward momentum flux.   EP flux divergence implies a source of Rossby wave activity, and EP flux convergence implies absorption of Rossby wave activity.  EP flux divergence represents the body force, or net effect of waves on the zonal mean zonal wind, with EP flux convergence causing deceleration of zonal mean westerlies and EP flux divergence causing acceleration. The primary effect of a region of EP flux convergence, however, is to induce poleward motion, with an associated mean meridional circulation and quadrupole of temperature anomalies in the meridional plane. EP fluxes are useful in investigating many planetary and synoptic scale weather phenomena such as the Quasi-Biennial Oscillation (QBO) and Sudden Stratospheric Warmings (SSWs).   The meridional and vertical components of the EP flux are calculated in pressure coordinates using the following initial conditions:  Ground density (rho_0 ):P_0/R_0/T_0 Ground pressure (P_0): 1013hPa Ground temperature (T_0): Temperature at 1000hPa Earth radius (a) = 6378km   Dimensions in the data: Latitude: 90°N-90°S (grid spacing is 0.25°, as in the ERA5 reanalysis)  Pressure: 1 hPa-1000 hPa (levels are the same as in the ERA5 reanalysis)  Time: January 1979 – December 2020; December, January, February (DJF) only; 00z and 12z 

   more » « less