Inner dynamic mechanism analysis for tropical cyclone rapid intensification based on FY-2 cloud motion

WANG Xin; GUO Qiang; WEN Rui

doi:10.11972/j.issn.1001-9014.2018.06.025

[4] Rappaport E N, Franklin J L, Avila L A, et al. Advances and challenges at the National Hurricane Center ［J］. Weather and Forecasting, 2009, 24(2): 395-419.

[6] Wang Y Q. How do outer spiral rainbands affect tropical cyclone structure and intensity ［J］. Journal of the Atmospheric Sciences, 2008, 66: 1250-1273.

[7] Hendricks E A, Peng M S, Fu B, et al. Quantifying environmental control on tropical cyclone intensity change ［J］. Monthly Weather Review, 2010, 138: 3243-3271.

[8] Hendricks E A. Internal dynamical control on tropical cyclone intensity variabitlity ［J］. Tropical Cyclone Research and Review, 2012, 1: 97-105.

[9] Wang Y Q, Rao Y J. A statistical analysis of the effects of vertical wind shear on tropical cyclone intensity change over the Western North Pacific ［J］. Monthly Weather Review, 2015, 143: 3434-3453.

[10] Rogers R. Convective-scale structure and evolution during a high-resolution simulation of tropical cyclone rapid intensification ［J］. Journal of the Atmospheric Sciences, 2010, 67(1): 44-70.

[13] Jiang H Y. The relationship between tropical cyclone intensity change and the strength of inner-core convection ［J］. Monthly Weather Review, 2012, 140: 1164-1176.

[14] Jiang H Y, Ramirez E M. Necessary conditions for Tropical cyclone rapid intensification as derived from 11 years of TRMM data ［J］, Journal of Climate, 2013, 26: 6459-6470.

[15] Zhuge X Y, Ming J, Wang Y. Reassessing the use of inner-core hot towers to predict tropical cyclone rapid intensification ［J］. Weather and Forecasting, 2008, 30(5): 1265-1279.

[16] Tao C, Jiang H. Global distribution of hot towers in tropical cyclones based on 11-yr TRMM data ［J］. Journal of Climate, 2013, 26: 1371-1386.

[17] Montgomery M T, Nicholls M E, Cram T A, et al. A vortical hot tower route to tropical cyclogenesis ［J］. Journal of the Atmospheric Sciences, 2006, 63: 355-386.

[18] Sarah M G, Kristopher M B, Christopher S V. A method for calculating the height of overshooting convective cloud tops using satellite-based IR imager and CloudSat cloud profiling radar observations ［J］. Journal of Applied Meteorology and Climatology, 2016, 55: 479-491.

[19] Shimada U, H Kubota, H Yamada, et al. Intensity and inner-core structure of typhoon Haiyan (2013) near landfall: Doppler radar analysis ［J］. Monthly Weathe Review, 2018, 146(2), 583-597.

[20] Sarah M G. Climatology of tropical overshooting tops in North Atlantic tropical cyclones ［J］. Journal of Applied Meteorology and Climatology, 2017, 56(6): 1783-1796.

[21] Guo Q, Wang X. Spatial-response matched filter and its application in radiometric accuracy improvement of FY-2 satellite thermal infrared band ［J］. IEEE Transactions on Geoscience and Remote Sensing, 2015, 53(5): 2397-2408.

[22] Wang X, Guo Q. Performance evaluation of objective tropical cyclone intensity determination with FY-2E/CIBLE results ［J］. Journal of Infrared and Millimeter Waves, 2014, 33(4): 442-449.

[23] Kaplan J, DeMaria M. Large-scale characteristics of rapidly intensifying tropical cyclones in the North Atlantic basin ［J］. Weather and Forecasting, 2003, 18(6): 1093-1108.