Abstract
Super Typhoon Haiyan was the most notable typhoon in 2013. In this study, results from the operational prediction of Haiyan by a tropical regional typhoon model for the South China Sea are analyzed. It is shown that the model has successfully reproduced Haiyan’s rapid passage through the Philippines and its northward deflection after its second landfall in Vietnam. However, the predicted intensity of Haiyan is weaker than the observed. An analysis of higher-resolution model simulations indicates that the storm is characterized by an upper-level warm core during its mature stage and a deep layer of easterly flow. Sensitivity experiments are conducted to study the impact of certain physical processes such as the interaction between stratus and cumulus clouds on the improvement of the typhoon intensity forecast. It is found that appropriate boundary layer and cumulus convective parameterizations, and orographic gravity-wave parameterization, as well as improved initial conditions and increased horizontal grid resolution, all help to improve the intensity forecast of Haiyan.
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References
Beljaars, A. C. M., 1994: The parameterization of surface fluxes in large-scale models under free-convection. Quart. J. Roy. Meteor. Soc., 121, 255–270.
Chen, H., D.-L. Zhang, J. Carton, et al., 2011: On the rapid intensification of Hurricane Wilma (2005). Part I: Model prediction and structural changes. Wea. Forecasting, 26, 885–901.
—, and —, 2013: On the rapid intensification of Hurricane Wilma (2005). Part II: Convective bursts and the upper-level warm core. J. Atmos. Sci., 70, 146–172.
Chen Dehui, 1995: New advance in forecast of tropical cy clone. Meteor. Sci. Technol., 22, 7–12. (in Chinese)
—, Wang Shiwen, and Wan Houjun, 1996: Performance of parameterization of sub-scale physical process in numerical model and its effects on typhoon track forecasting. J. Appl. Meteor. Sci., 7, 1–8. (in Chinese)
Dai Guangfeng and Chen Zitong, 2013: Sensitive experiments of the surface flux on a simulated typhoon in GRAPES. J. Trop. Meteor., 29, 403–410. (in Chinese)
Han, J., and H. L. Pan, 2011: Revision of convection and vertical diffusion schemes in the NCEP global forecast system. Wea. Forecasting, 26, 520–533.
He Bin, 2006: Sensitive experiments of Typhoon “MATSA” to parameters used in WRF model. Memoir of Parallel Sessions “Mesoscale Weather Dynamic, Numerical Simulation, and Prediction,” Annual Meeting of the Chinese Meteorological Society, Chengdu, 25–27 October 2006, Chinese Meteor. Soc., 283–289.
He Huiqing, Wang Zhenhui, Jing Zhengrun, et al., 2011: The impact of cumulus parameterizations and microphysics schemes under different combinations on typhoon track prediction. J. Trop. Meteor., 17, 113–119. (in Chinese)
Kaplan, J., and M. DeMaria, 2003: Large-scale characteristics of rapidly intensifying tropical cyclones in the North Atlantic basin. Wea. Forecasting, 18, 1093–1108.
Kasahara, A., 1957: The numerical prediction of hurricane movement with the barotropic model. J. Meteor., 14, 386–402.
Kim, Y. J., and A. Arakawa, 1995: Improvement of orographic gravity wave parameterization using a mesoscale gravity wave model. J. Atmos. Sci., 52, 1875–1902.
Ma Yufen, Shen Tongli, Ding Zhiying, et al., 2009: Numerical simulation and orographic sensitive experiments of Typhoon Saomai during landfall. J. Nanjing Inst. Meteor., 32, 277–286. (in Chinese)
Ni Yunqi, Jin Hanliang, and Xue Zhongyuan, 1981: An operational numerical forecasting scheme of typhoon tracks over the western Pacific and its preliminary results. Chinese J. Atmos. Sci., 5, 281–291. (in Chinese)
Pan, H. L., and W. S. Wu, 1995: Implementing a mass flux convective parameterization package for the NMC medium range forecast model. NMC Office Note 409, 40 pp.
Pun, I.-F., I.-I. Lin, and M.-H. Lo, 2013: Recent increase in high tropical cyclone heat potential area in the western North Pacific Ocean. Geophys. Res. Lett., 40, 4680–4684.
Rogers, R., 2010: Convective-scale structure and evolution during a high-resolution simulation of tropical cyclone rapid intensification. J. Atmos. Sci., 67, 44–70.
Shi Lijuan, Xu Xiaofeng, Li Bai, et al., 2009: Application of Doppler radar data to the simulation of land-falling Typhoon Saomai. J. Appl. Meteor. Sci., 20, 257–266. (in Chinese)
Wang Kangling, Xue Jishan, and Liang Yanzhao, 1987: Split semi-implicit integration of tropical limited area multi-level primitive equation model. Acta Meteor. Sinica, 1, 123–132.
Wang Shiwen and Li Jianjun, 1994: Experiments of real-time numerical weather prediction of typhoon tracks. J. Appl. Meteor. Sci., 5, 462–469. (in Chinese)
Xu Yinglong, Zhang Ling, and Gao Shuanzhu, 2010: The advances and discussions on China operational typhoon forecasting. Meteor. Mon., 36, 43–49. (in Chinese)
Xue Jishan, Wang Kangling, Wang Zhiming, et al., 1988: Test of a tropical limited area numerical prediction model including effect of real topography. Adv. Atmos. Sci., 5, 1–23.
—, —, and He Anguo, 1996: Upgrade of tropical limited-area numerical model and application in typhoon forecast. J. Appl. Meteor. Sci., 2, 120–128. (in Chinese)
Yu Yubin, Duan Haixia, Yan Lijun, et al., 2008: Numerical simulation of rapid intensification change of Super Typhoon Saomai (2006) over the coastal water of China. Chinese J. Atmos. Sci., 32, 1365–1378. (in Chinese)
Zhang, D.-L., and H. Chen, 2012: Importance of the upper-level warm core in the rapid intensification of a tropical cyclone. Geophys. Res. Lett., 39, L02806, doi: 10.1029/2011GL050578.
Zhong Shuixin, Chen Zitong, Dai Guangfeng, et al., 2014: Impacts of orographic gravity wave drag parameterization on the intensity and path forecasting of typhoon. Chinese J. Atmos. Sci., 38, 273–284. (in Chinese).
Zhu Yongti, Xu Yiming, Hu Fuquan, et al., 1982: An experiment in numerical forecasting of typhoon tracks with nested models. Acta Meteor. Sinica, 40, 257–270. (in Chinese)
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Supported by the China Meteorological Administration Special Public Welfare Research Fund (GYHY201206010) and Guangdong Science and Technology Research Plan (2012A061400012 and 2011A032100006).
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Chen, Z., Zhang, C., Huang, Y. et al. Track of Super Typhoon Haiyan predicted by a typhoon model for the South China Sea. J Meteorol Res 28, 510–523 (2014). https://doi.org/10.1007/s13351-014-3269-2
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DOI: https://doi.org/10.1007/s13351-014-3269-2