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Quantifying stratospheric biases and identifying their potential sources in subseasonal forecast systems

Cited 12 time in Web of Science Cited 13 time in Scopus
Authors

Lawrence, Zachary D.; Abalos, Marta; Ayarzagüena, Blanca; Barriopedro, David; Butler, Amy H.; Calvo, Natalia; de la Cámara, Alvaro; Charlton-Perez, Andrew; Domeisen, Daniela I.V.; Dunn-Sigouin, Etienne; García-Serrano, Javier; Garfinkel, Chaim I.; Hindley, Neil P.; Jia, Liwei; Jucker, Martin; Karpechko, Alexey Y.; Kim, Hera; Lang, Andrea L.; Lee, Simon H.; Lin, Pu; Osman, Marisol; Palmeiro, Froila M.; Perlwitz, Judith; Polichtchouk, Inna; Richter, Jadwiga H.; Schwartz, Chen; Son, Seok-Woo; Statnaia, Irina; Taguchi, Masakazu; Tyrrell, Nicholas L.; Wright, Corwin J.; Wu, Rachel W.-Y.

Issue Date
2022-08
Publisher
Copernicus Publications
Citation
Weather and Climate Dynamics, Vol.3 No.3, pp.977-1001
Abstract
© Author(s) 2022.The stratosphere can be a source of predictability for surface weather on timescales of several weeks to months. However, the potential predictive skill gained from stratospheric variability can be limited by biases in the representation of stratospheric processes and the coupling of the stratosphere with surface climate in forecast systems. This study provides a first systematic identification of model biases in the stratosphere across a wide range of subseasonal forecast systems. It is found that many of the forecast systems considered exhibit warm global-mean temperature biases from the lower to middle stratosphere, too strong/cold wintertime polar vortices, and too cold extratropical upper-troposphere/lower-stratosphere regions. Furthermore, tropical stratospheric anomalies associated with the Quasi-Biennial Oscillation tend to decay toward each systems climatology with lead time. In the Northern Hemisphere (NH), most systems do not capture the seasonal cycle of extreme-vortex-event probabilities, with an underestimation of sudden stratospheric warming events and an overestimation of strong vortex events in January. In the Southern Hemisphere (SH), springtime interannual variability in the polar vortex is generally underestimated, but the timing of the final breakdown of the polar vortex often happens too early in many of the prediction systems. These stratospheric biases tend to be considerably worse in systems with lower model lid heights. In both hemispheres, most systems with low-top atmospheric models also consistently underestimate the upward wave driving that affects the strength of the stratospheric polar vortex. We expect that the biases identified here will help guide model development for subseasonal-to-seasonal forecast systems and further our understanding of the role of the stratosphere in predictive skill in the troposphere.
ISSN
2698-4016
URI
https://hdl.handle.net/10371/205445
DOI
https://doi.org/10.5194/wcd-3-977-2022
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  • College of Natural Sciences
  • Department of Earth and Environmental Sciences
Research Area Climate Change, Polar Environmental, Severe Weather, 극지환경, 기후과학, 위험기상

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