ID:
publications-1500
Type:
PEER REVIEWED ARTICLE
Year:
2019
Authors:
Cameron D. Rae , James Keeble , Peter Hitchcock , John A. Pyle
Title:
Prescribing Zonally Asymmetric Ozone Climatologies in Climate Models: Performance Compared to a ChemistryâClimate Model
Venue/Journal:
DOI:
10.1029/2018ms001478
Research type:
Data Management & Analytics
Water System:
Precipitation & Ecological Systems
Technical Focus:
Abstract:
AbstractThree different methods of specifying ozone in an atmosphereâonly version of the HadGEM3âA global circulation model are compared to the coupled chemistry configuration of this model. These methods include a specified zonalâmean ozone climatology, a specified 3âD ozone climatology, and a calculatedâasymmetry scheme in which a specified zonalâmean ozone field is adapted online to be consistent with dynamically produced zonal asymmetries. These simulations all use identical boundary conditions and, by construction, have the same climatological zonalâmean ozone, that of the coupled chemistry configuration of the model. Prescribing ozone, regardless of scheme, results in a simulation which is 3â4 times faster than the coupled chemistryâclimate model (CCM). Prescribing climatological zonal asymmetries leads to a vortex which is the correct intensity but which is systematically displaced over regions with lower prescribed ozone. When zonal asymmetries in ozone are free to evolve interactively with model dynamics, the modeled wintertime stratospheric vortex shape and mean sea level pressure patterns closely resemble that produced by the full CCM in both hemispheres, in terms of statistically significant differences. Further, we separate out the two distinct pathways by which zonal ozone asymmetries influence modeled dynamics. We present this interactiveâozone zonalâasymmetry scheme as an inexpensive tool for accurately modeling the impacts of dynamically consistent ozone fields as seen in a CCM which ultimately influence mean sea level pressure and tropospheric circulation (particularly during wintertime in the Northern Hemisphere, when ozone asymmetries are generally largest), without the computational burden of simulating interactive chemistry.
Link with Projects:
603557
Link with Tools:
Related policies:
ID:
