Intraseasonal shift in the wintertime North Atlantic jet structure projected by CMIP6 models

npj Climate and Atmospheric Science Nature Research 7:1 (2024) 234

Authors:

Marina García-Burgos, Blanca Ayarzagüena, David Barriopedro, Tim Woollings, Ricardo García-Herrera

Abstract:

The projected winter changes of the North Atlantic eddy-driven jet (EDJ) under climate change conditions have been extensively analysed. Previous studies have reported a squeezed and elongated EDJ. However, other changes present large uncertainties, specifically those related to the intensity and latitude. Here, the projections of the EDJ in a multimodel ensemble of CMIP6 are scrutinised by using a multiparametric description of the EDJ. The multimodel mean projects non-stationary responses of the EDJ latitude through the winter, characterised by a poleward shift in early winter and equator migration in late winter. These intraseasonal shifts (rather than a genuine narrowing) explain the previously established squeezing of the EDJ and are linked to the future changes in different drivers: the 200 hPa meridional temperature gradient and Atlantic warming hole in early winter, and the stratospheric vortex in late winter. Model biases also influence EDJ projections, contributing to the poleward shift in early winter.

Drivers of the ECMWF SEAS5 seasonal forecast for the hot and dry European summer of 2022

Quarterly Journal of the Royal Meteorological Society Wiley (2024)

Authors:

Matthew Patterson, Daniel J Befort, Christopher H O'Reilly, Antje Weisheimer

Supplementary material to "Solar cycle impacts on North Atlantic climate"

(2024)

Authors:

Paula LM Gonzalez, Lesley J Gray, Stergios Misios, Scott Osprey, Hedi Ma

A momentum budget study of the semi-annual oscillation in the Whole Atmosphere Community Climate Model

Quarterly Journal of the Royal Meteorological Society, 1–22

Authors:

Aleena M. Jaison, Lesley J. Gray, Scott Osprey, Anne K. Smith, Rolando R. Garcia

Abstract:

The representation of the semi-annual oscillation (SAO) in climate models shows a common easterly bias of several tens of metres per second compared to observations. These biases could be due to deficiencies in eastward tropical wave forcing, the position or strength of the climatological summertime jet or the strength/timing of the Brewer–Dobson circulation. This motivates further analysis of the momentum budget of the upper stratosphere within models and a more detailed comparison with reanalyses to determine the origin of the bias. In this study, the transformed Eulerian mean momentum equation is used to evaluate the different forcing terms that contribute to the SAO in the MERRA2 reanalysis dataset. This is then compared with the equivalent analysis using data from a climate simulation of the Whole Atmosphere Community Climate Model (WACCM). The comparison shows that WACCM underestimates eastward forcing by both resolved and parameterised waves at equatorial latitudes when compared with MERRA2 and also has a weaker tropical upwelling above 1 hPa.

A momentum budget study of the semi‐annual oscillation in the Whole Atmosphere Community Climate Model

Quarterly Journal of the Royal Meteorological Society Wiley (2024)

Authors:

Aleena M Jaison, Lesley J Gray, Scott Osprey, Anne K Smith, Rolando R Garcia

Abstract:

The representation of the semi‐annual oscillation (SAO) in climate models shows a common easterly bias of several tens of metres per second compared to observations. These biases could be due to deficiencies in eastward tropical wave forcing, the position or strength of the climatological summertime jet or the strength/timing of the Brewer–Dobson circulation. This motivates further analysis of the momentum budget of the upper stratosphere within models and a more detailed comparison with reanalyses to determine the origin of the bias. In this study, the transformed Eulerian mean momentum equation is used to evaluate the different forcing terms that contribute to the SAO in the MERRA2 reanalysis dataset. This is then compared with the equivalent analysis using data from a climate simulation of the Whole Atmosphere Community Climate Model (WACCM). The comparison shows that WACCM underestimates eastward forcing by both resolved and parameterised waves at equatorial latitudes when compared with MERRA2 and also has a weaker tropical upwelling above 1 hPa.