[1] RAMAGE C S. Hurricane Development [J]. J. Meteor., 1959, 16(3): 227-237.
[2] MERRILL R T. Environmental influences on hurricane intensification [J]. J. Atmos. Sci., 1988, 45(11): 1678-1687.
[3] GRAY W M. Global view of the origin of tropical disturbances and storms [J]. Mon. Wea. Rev., 1968, 96(10): 669-700.
[4] McBRIDE J L, ZEHR R M. Observational analysis of tropical cyclone formation. Part II: Comparison of non-developing versus developing systems [J]. J. Atmos. Sci., 1981, 38(6): 1132-1151.
[5] TULEYA R E, KURIHARA Y. A numerical study on the effects of environmental flow on tropical storm genesis [J]. Mon. Wea. Rev., 1981, 109(12): 2487-2506.
[6] ZEHR R M. Tropical cyclogenesis in the western North Pacific [R]. NOAA Tech. Rep., NESDIS, 1992, 61: 181pp.
[7] GALLINA G M, VELDEN C S. Environmental vertical wind shear and tropical cyclone intensity change utilizing enhanced satellite derived wind information [C]// Extended Abstracts, 25th Conf. on Hurricanes and Tropical Meteorology, San Diego: Amer. Meteor. Soc., 2002: 172-173.
[8] SIMPSON R H, RIEHL H. Mid-tropospheric ventilation as a constraint on hurricane development and maintenance [C]// Proc. Technical Conf. on Hurricanes, Miami Beach: Amer. Meteor Soc., 1958: D4.1-D4.10.
[9] JONES S C. The evolution of vortices in vertical shear. I: Initially barotropic vortices [J]. Quart. J. Roy. Meteor. Soc., 1995, 121(524): 821-851.
[10] MARKS F D Jr, HOUZE R A Jr, GAMACHE J F. Dual-aircraft investigation of the inner core of Hurricane Norbert. Part I: Kinematic structure [J]. J. Atmos. Sci., 1992, 49(11): 919-942.
[11] FRANKLIN J L, LORD S J, FEUER S E, et al. The kinematic structure of Hurricane Gloria (1985) determined from nested analyses of dropwinsonde and Doppler wind data[J]. Mon. Wea. Rev., 1993, 121(9): 2433-2451.
[12] CORBOSIERO K L, MOLINARI J. The effects of vertical wind shear on the distribution of convection in tropical cyclones [J]. Mon. Wea. Rev., 2002, 130(8): 2100-2123.
[13] CORBOSIERIO K L, MOLINARI J. The relationship between storm motion, vertical wind shear and convection asymmetries in tropical cyclones [J]. J. Atmos. Sci., 2003, 60(2): 366-376.
[14] DeMARIA M. The effect of vertical wind shear on tropical cyclone intensity change [J]. J. Atmos. Sci., 1996, 53(14): 2076-2087.
[15] FRANK W M, RITCHIE E A. Effects of vertical wind shear on the intensity and structure of numerically simulated hurricanes [J]. Mon. Wea. Rev., 2001, 129(9): 2249-2269.
[16] FRANK W M, RITCHIE E A. Tropical cyclones in complex vertical shears [C]// Extended Abstracts, 25th Conf. on Hurricanes and Tropical Meteorology, San Diego: Amer. Meteor. Soc., 2002: 315-316.
[17] BLACK M L, GAMACHE J F, MARKS JR F D, et al. Eastern Pacific Hurricanes Jimena of 1991and Olivia of 1994: The effect of vertical shear on structure and intensity [J]. Mon. Wea. Rev., 2002, 130(9): 2291-2312.
[18] MOLINARI J, VOLLARO D, CORBOSIERIO K L. Tropical cyclone formation in a sheared environment: A case study [J]. J. Atmos. Sci., 2004, 61(21): 2493-2509.
[19] JONES S C. The evolution of vortices in vertical shear. II: Large-scale asymmetries [J]. Quart. J. Roy. Meteor. Soc., 2000, 126(570): 3137-3159.
[20] JONES S C. The evolution of vortices in vertical shear. III: Baro-clinic vortices [J]. Quart. J. Roy. Meteor. Soc., 2000, 126(570): 3161-3185.
[21] JONES S C. On the ability of dry tropical-cyclone-like vortices to withstand vertical shear [J]. J. Atmos. Sci., 2004, 61(1): 114-119.
[22] WONG M L M, CHAN J C L. Tropical cyclone intensity in vertical wind shear [J]. J. Atmos. Sci., 2004, 61(15): 1859-1876.
[23] ZHANG D L, KIEU C Q. Shear-forced vertical circulations in tropical cyclones [J]. Geophys. Res. Lett., 2005, 32(L13822): 1-4.
[24] REASOR P D, MONTGOMERY M T, GRASSO L D. A new look at the problem of tropical cyclones in vertical shear flow: Vortex resiliency [J]. J. Atmos. Sci., 2004, 61(1): 3-22.
[25] SCHECTER D A, MONTGOMERY M T. Waves in a cloudy vortex [J]. J. Atmos. Sci., 2007, 64(2): 314-337.
[26] HONG S Y, DUDHIA J, CHEN S H. A revised approach to ice microphysical processes for the bulk parameterization of clouds and precipitation [J]. Mon. Wea. Rev., 2004, 132(1): 103-120.
[27] NOH Y, CHEON W G, HONG S Y, et al. Improvement of the K-profile model for the planetary boundary layer based on large eddy simulation data [J]. Bound.-Layer Meteor., 2003, 107(2): 401-427.
[28] NGUYEN V S, SMITH R K, MONTGOMERY M T. Tropical cyclone intensification and predictability in three dimensions [J]. Quart. J. Roy. Meteor. Soc., 2008, 134(632): 563-582.
[29] NOLAN D S. What is the trigger for tropical cyclogenesis?[J]. Aust. Meteor. Mag., 2007, 56(4): 241-266.
[30] JORDAN C L. Mean soundings for the West Indies area[J]. J. Meteor., 1958, 15(1): 91-97.
[31] ROTUNNO R, EMANUEL K A. An air�Csea interaction theory for tropical cyclones. Part II: Evolutionary study using a nonhydrostatic axisymmetric numerical model [J]. J. Atmos. Sci., 1987, 44(3): 542-561.
[32] FRANK W M, RITCHIE E A. Effects of environmental flow on tropical cyclone structure [J]. Mon. Wea. Rev., 1999, 127(9): 2044-2061.
[33] KNAFF J A, SESESKE S A, DEMARIA M, et al. On the influences of vertical wind shear on symmetric tropical cyclone structure derived from AMSU [J]. Mon. Wea. Rev., 2004, 132(10): 2503-2510.
[34] YUTER S E, HOUZE JR R A. Three-dimensional kinematic and microphysical evolution of Florida cumulonimbus. Part III: Vertical mass transport, mass divergence, and synthesis [J]. Mon. Wea. Rev., 1995, 123(7): 1964-1983.
[35] BLACK M L, BURPEE R W, MARKS JR F D. Vertical motion characteristics of tropical cyclones determined with airborne Doppler radial velocities [J]. J. Atmos. Sci., 1996, 53(13): 1887-1909.
[36] ROGERS R F, BLACK M L, CHEN S S, et al. An evaluation of microphysics fields from mesoscale model simulation of tropical cyclones. Part I: Comparisons with observations [J]. J. Atmos. Sci., 2007, 64(6): 1811-1834.
[37] ZHANG F, SIPPEL J A. Effects of moist convection on hurricane predictability [J]. J. Atmos. Sci., 2009, 66(7): 1944-1961.
[38] FAMG J, ZHANG F. Initial development and genesis of Hurricane Dolly (2008) [J]. J. Atmos. Sci., 2010, 67(3): 655-672.
[39] MONTGOMERY M T, NICHOLLS M E, CRAM T A, et al. A vortical hot tower route to tropical cyclogenesis [J]. J. Atmos. Sci., 2006, 63(1): 355-386.
[40] TORY K J, MONTGOMERY M T. Tropical cyclone formation: A synopsis of the internal dynamics [C/OL]. Preprints, 28th Conf. on Hurricanes and Tropical Meteorology, Orlando: Amer. Meteor. Soc, 2008, 10A.1. [2011-09-30] http://ams.confex.com/ams/28Hurricanes/techprogram/paper_1 38062.htm
[41] SKAMAROCK W C, COAUTHORS. A description of the Advanced Research WRF version 2 [R]. NCAR Tech. Note NCAR/TN-4681STR, 2005: 88pp.