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Dynamics of eddy-driven North Atlantic Oscillations in a localized shifting jet: zonal structure and downstream blocking

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Abstract

In a weakly nonlinear model how an initial dipole mode develops to the North Atlantic Oscillation (NAO) in a localized shifting jet under the prescribed eddy forcing is examined. It is found that the zonal structure of the eddy-driven NAO anomaly is not only dominated by the longitudinal distribution of the preexisting Atlantic storm track, but also by the initial condition of the NAO anomaly itself associated with the interaction between a localized shifting jet and a topographic standing wave over the Atlantic basin. When both the initial NAO anomaly and the eddy vorticity forcing in the prior Atlantic storm track are more zonally localized, the subsequent eddy-driven NAO anomaly can be more zonally isolated and asymmetric. But, it seems that the shape of the initial NAO anomaly associated with the latitudinal shift of a prior Atlantic jet plays a more important role in producing the zonal asymmetry of subsequent NAO patterns. The zonal asymmetry of the NAO anomaly can be enhanced as the height of topography increases. In addition, it is further found that blocking events occur easily over the Europe continent through the decaying of positive-phase NAO events. However, prior to the positive-phase NAO life cycle the variability in each of three factors: the Atlantic jet, the eddy vorticity forcing in the Atlantic storm track and the initial NAO anomaly can result in a variation in the blocking activity over the Europe sector in strength, duration, position and pattern.

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Acknowledgments

Most part of this paper is carried out when the first author is a visiting scientist at the City University of Hong Kong supported by the City-U Strategic Research Grant 7002231. The authors also acknowledge the support from National Basic Research Project of China (2007CB411803) and the Joint National Natural Science Foundation of China project (U0733002). The authors would like to thank two anonymous reviewers for their useful suggestions in improving this paper.

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Authors and Affiliations

  1. College of Physical and Environmental Oceanography, Ocean University of China, 266003, Qingdao, China

    Dehai Luo

  2. CityU-IAP Laboratory for Atmospheric Sciences, Department of Physics and Material Sciences, City University of Hong Kong, Hong Kong, China

    Dehai Luo, Wen Zhou & Ke Wei

  3. Center for Monsoon System Research, IAP, Chinese Academy of Science, Beijing, China

    Ke Wei

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  1. Dehai Luo
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  2. Wen Zhou
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  3. Ke Wei
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Correspondence to Dehai Luo.

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Luo, D., Zhou, W. & Wei, K. Dynamics of eddy-driven North Atlantic Oscillations in a localized shifting jet: zonal structure and downstream blocking. Clim Dyn 34, 73–100 (2010). https://doi.org/10.1007/s00382-009-0559-y

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  • DOI: https://doi.org/10.1007/s00382-009-0559-y

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