A nonlinear multiscale interaction model for atmospheric blocking: The eddy‐blocking matching mechanism

A nonlinear multiscale interaction model for atmospheric blocking: The eddy‐blocking matching mechanism

In this article, a nonlinear multiscale interaction (NMI) model is used to propose an eddy‐blocking matching (EBM) mechanism to account for how synoptic eddies reinforce or suppress a blocking flow. It is shown that the spatial structure of the eddy vorticity forcing (EVF) arising from upstream syno...

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Bibliographic Details
Published in:Quarterly journal of the Royal Meteorological Society 2014-07, Vol.140 (683), p.1785-1808
Main Authors: Luo, Dehai, Cha, Jing, Zhong, Linhao, Dai, Aiguo
Format: Article
Language:eng
Subjects:
blocking
Brackish
Earth, ocean, space
eddy straining
Exact sciences and technology
External geophysics
General circulation. Atmospheric waves
Geophysics. Techniques, methods, instrumentation and models
Marine
Meteorology
multiscale interaction
synoptic eddies
Weather
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Summary:In this article, a nonlinear multiscale interaction (NMI) model is used to propose an eddy‐blocking matching (EBM) mechanism to account for how synoptic eddies reinforce or suppress a blocking flow. It is shown that the spatial structure of the eddy vorticity forcing (EVF) arising from upstream synoptic eddies determines whether an incipient block can grow into a meandering blocking flow through its interaction with the transient synoptic eddies from the west. Under certain conditions, the EVF exhibits a low‐frequency oscillation on time‐scales of 2–3 weeks. During the EVF phase with a negative‐over‐ positive dipole structure, a blocking event can be resonantly excited through the transport of eddy energy into the incipient block by the EVF. As the EVF changes into an opposite phase, the blocking decays. The NMI model produces life cycles of blocking events that resemble observations. Moreover, it is shown that the eddy north–south straining is a response of the eddies to a dipole‐ or Ω‐type block. In our model, as in observations, two synoptic anticyclones (cyclones) can attract and merge with one another as the blocking intensifies, but only when the feedback of the blocking on the eddies is included. Thus, we attribute the eddy straining and associated vortex interaction to the feedback of the intensified blocking on synoptic eddies. The results illustrate the concomitant nature of the eddy deformation, the role of which, as a potential vorticity source for the blocking flow, becomes important only during the mature stage of a block. Our EBM mechanism suggests that an incipient block flow is amplified (or suppressed) under certain conditions by the EVF coming from the upstream of the blocking region. This also suggests that weather and climate models need to be run with a grid size below 100 km in order to simulate the matching EVF and thus atmospheric blocking.
ISSN:0035-9009
1477-870X