We have been challenging the simulation of tropical cyclone (TC) geneses using a global/regional cloud-system resolving model (GCSRM), non-hydrostatic ICosahedral-grid atmospheric model (NICAM) (Satoh et al. 2008). A GCSRM has the advantages that it can deal with the organization of meso-scale cloud systems into a tropical cyclone during the cyclogenesis process, and that it can cover the long-distance movement of TC sources such as tropical waves. Using a GCSRM, our goal is to reveal the relation between predictabilities and mechanisms of TC geneses. In the previous studies, two important perspectives have been suggested related to TC geneses: environments and sources. The large-scale environments explain probability distribution of TC geneses including climatological seasonal change, interannual variability like ENSO, and intraseasonal oscillation such as Madden-Julian Oscillation. On the other hand, the precise timings of TC geneses seem to be triggered by synoptic-scale sources such as tropical waves, extratropical disturbances, and energy dispersions from neighboring TCs. Recently we have demonstrated that the 14-km-grid GCSRM can predict the timing of Typhoon 21st in 2006 with the lead time of more than 3 days, which was controlled by the westward propagating wave over the North Pacific. In 2008, Cyclone Nargis caused terrible disaster in Myanmar; we examined the predictability of Nargis genesis using the NICAM model. © 2010 Springer Science+Business Media B.V.
CITATION STYLE
Yanase, W., Taniguchi, H., & Satoh, M. (2010). Numerical simulation of the genesis of cyclone nargis using a global cloud-system resolving model, NICAM. In Indian Ocean Tropical Cyclones and Climate Change (pp. 65–72). Springer Netherlands. https://doi.org/10.1007/978-90-481-3109-9_10
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