A Novel Gravity Wave Transport Parametrization for Global Chemistry Climate Models: Description and Validation

DOI: 
10.1029/2023MS003938
Publication date: 
11/05/2024
Main author: 
Guarino, Maria-Vittoria
IAA authors: 
Funke, Bernd;García-Comas, Maya;López-Puertas, Manuel
Authors: 
Guarino, Maria-Vittoria;Gardner, Chester S.;Feng, Wuhu;Funke, Bernd;García-Comas, Maya;López-Puertas, Manuel;Kupilas, Marcin M.;Marsh, Daniel R.;Plane, John M. C.
Journal: 
Journal of Advances in Modeling Earth Systems
Publication type: 
Article
Volume: 
16
Pages: 
e2023MS003938
Abstract: 
The gravity wave drag parametrization of the Whole Atmosphere Community Climate Model (WACCM) has been modified to include the wave-driven atmospheric vertical mixing caused by propagating, non-breaking, gravity waves. The strength of this atmospheric mixing is represented in the model via the "effective wave diffusivity" coefficient (K<SUB>wave</SUB>). Using K<SUB>wave</SUB>, a new total dynamical diffusivity (K<SUB>Dyn</SUB>) is defined. K<SUB>Dyn</SUB> represents the vertical mixing of the atmosphere by both breaking (dissipating) and vertically propagating (non-dissipating) gravity waves. Here we show that, when the new diffusivity is used, the downward fluxes of Fe and Na between 80 and 100 km largely increase. Larger meteoric ablation injection rates of these metals (within a factor 2 of measurements) can now be used in WACCM, which produce Na and Fe layers in good agreement with lidar observations. Mesospheric CO<SUB>2</SUB> is also significantly impacted, with the largest CO<SUB>2</SUB> concentration increase occurring between 80 and 90 km, where model-observations agreement improves. However, in regions where the model overestimates CO<SUB>2</SUB> concentration, the new parametrization exacerbates the model bias. The mesospheric cooling simulated by the new parametrization, while needed, is currently too strong almost everywhere. The summer mesopause in both hemispheres becomes too cold by about 30 K compared to observations, but it shifts upward, partially correcting the WACCM low summer mesopause. Our results highlight the far-reaching implications and the necessity of representing vertically propagating non-breaking gravity waves in climate models. This novel method of modeling gravity waves contributes to growing evidence that it is time to move away from dissipative-only gravity wave parametrizations.
Database: 
ADS
URL: 
https://ui.adsabs.harvard.edu/#abs/2024JAMES..1603938G/abstract
ADS Bibcode: 
2024JAMES..1603938G
Keywords: 
gravity waves;MLT;metal layer;climate modeling;constituent transport;atmospheric mixing