TOGA—COARE强化期（IOP）西太平洋海域的辐射特征

该利用ＴＯＧＡ－ＣＯＡＲＥ强化观测期（ＩＯＰ）所获得的辐射观测资料（１９９２年１１月１０日－１９９３年２月１８日），对考察点（２°１５′Ｓ，１５８°００′）的辐射分量进行了分析，其中包括总辐射、直接辐射、散射辐射、海表长波辐射、大气逆辐射、海表反射辐射春反照率、净辐射及有效辐射。     

TOGA－COARE强化期（IOP）西太平洋海域的辐射特征

该文利用ＴＯＧＡ－ＣＯＡＲＥ强化观测期（ＩＯＰ）所获得的辐射观测资料（１９９２年１１月１０日—１９９３年２月１８日），对考察点（２°１５′Ｓ，１５８°００′Ｅ）的辐射分量进行了分析，其中包括总辐射、直接辐射、散射辐射、海表长波辐射、大气逆辐射、海表反射辐射及其反照率、净辐射及有效辐射。结果表明：和其它地区（如高原）比较，观测点的总辐射、直接辐射均很强；反射率小，晴天平均为０．０４—０．０５，阴天为０．０６—０．０８；海表长波辐射大而日变化小，大气逆辐射强而日变化大；有效辐射小而净辐射大。     

西太平洋热带海域强对流天气过程湍流通量输送的某些特征

本根据“实验３号”科学考察船在ＴＯＧＡ－ＣＯＡＲＥ（１９９２年１１月－１９９３年２月）定点（２°１５＇Ｓ，１５８°００＇Ｅ）连续观测的大气，海洋资料，利用考虑风速和大气层结影响的整体输送动力学公式，计算给出了在西太平洋热带海域强对流天气过程中动量、感热和潜热等湍流通量垂直交换和水平输送的一些特性，并与该海域其它天气过程湍流通量交换和输送的特性作了比较，此外，中还讨论了更接近实际的曳力系数，感热     

SST日变化对西太平洋暖池海表热通量季节内变化的影响(英文)

基于利用日最大太阳辐射、日平均海面风和日降水量近似计算海表温度（SST）日变化的振幅的方法,发展了一个计算SST日循环的参数化方案。利用周平均SST强迫美国国家大气研究中心（NCAR）的CCM3大气模式进行了有、无考虑SST日变化的比较试验。热带海洋与全球大气计划之耦合海气响应实验（TOGA COARE）的强化观测期间 IMET浮标的逐时海表观测资料不仅验证了该参数化方案的合理性,也表明了利用参数化方案对强迫场SST迭加日变化使CCM3较真实地模拟出西太平洋暖池海表热通量的季节内变化的位相结构。     

CHARACTERISTICS OF HEAT FLUX OVER THE TROPICAL WESTERN PACIFIC DURING THE IOP OF TOGA-COARE

Based on the surface meteorological and radiosonde data during the IOP of TOGA-COARE (Tropical Ocean Global Atmospheric-Coupled Ocean Atmospheric Response Experiment) at the observation site (2°15′S, 158°E)of "R/V Shiyan 3", characteristics of the heat flux, especially that pertaining two WWBs (westerly wind bursts)over the tropical western Pacific for the IOP, are exhaustively analyzed. Meanwhile, the relationships among large-scale circulation and mid-and-high latitude circulation are discussed. The results show that the latent and sensible heat fluxes from sea surface to air over the tropical western Pacific are very strong in both the WWBs,and that their causes of formation have important relations with cross-equatorial flow from the winter hemisphere,and the heat exchange over sea surface varies with different weather condition.     

THE CHARACTERISTICS OF AIR-SEA HEAT FLUX EXCHANGE DURING THE GENERATION AND DEVELOPMENT OF LOCAL TYPHOONS OVER THE SOUTH CHINA SEA

A South China Sea （SCS） local TC （SLT） is defined as a tropical cyclone （TC） that forms within the SCS region and can reach the grade of tropical storm （TS） or above. The statistical features of the SLTs from 1985 to 2007 are analyzed first. It is found that over the SCS about 68% of the TCs can develop into TSs. The SLT intensity is relatively weak and associated with its genesis latitude as well as its track. The SLT monthly number presents a seasonal variation with two peaks in May and July to September. Based on the daily heat flux data from the Woods Hole Oceanographic Institution_Objectively Analyzed air-sea Fluxes （WHOI_OAFlux） in the same period, the air-sea exchange during the process of generation and development of the SLT is studied. Results show that the heat fluxes released to the atmosphere increase significantly day by day before cyclogenesis. The ocean to the south to the TC center provides the main energy. Along with the development of SLT, the regions with large heat fluxes spread clockwise to the north of TC, which reflects the energy dispersion property of vortex Rossby waves in the periphery of the TC. Once the SLT forms the heat fluxes are not intensified as much. During the whole process, the net heat, latent heat and sensible heat flux display a similar evolution, while the latent heat flux makes a main contribution to the net heat flux. The maximum air-sea heat exchange always occurs at the left side of the TC moving direction, which may reflect the influence of the SCS summer monsoon on TC structure.     

IMPACT OF CONVECTION OVER THE SOUTH CHINA SEA ON TROPICAL CYCLONE MOTION OVER THE WESTERN NORTH PACIFIC DURING SUMMER MONSOON

The intraseasonal oscillation(ISO) of the South China Sea(SCS, 105-120°E, 5-20°N) convection and its influences on the genesis and track of the western North Pacific(WNP) tropical cyclones(TCs) were explored, based on the daily average of NCEP/NCAR reanalysis data, the OLR data and the western North Pacific tropical cyclone best-track data from 1979 to 2008. The mechanism of the influences of ISO on TC movement and the corresponding large-scale circulation were discussed by a trajectory model. It was found as follows.(1) During the SCS summer monsoon, the SCS convection exhibits the ISO features with active phases alternating with inactive phases. The monsoon circulation patterns are significantly different during these two phases. When the SCS convection is active(inactive), the SCS-WNP monsoon trough stretches eastward(retreats westward) due to the activity(inactivity) of SCS monsoon, and the WNP subtropical high retreats eastward(stretches westward), which enhances(suppresses) the monsoon circulation.(2) The amount of TC genesis in the active phase is much more than that in the inactive phase. A majority of TCs form west of 135 °E during the active phases but east of 135 °E in the inactive phases.(3) The TCs entering the area west of 135 °E and south of 25 °N would move straight into the SCS in the active phase, or recurve northward in the inactive phase.(4) Simulation results show that the steering flow associated with the active(inactive)phases is in favor of straight-moving(recurving) TCs. Meanwhile, the impacts of the locations of TC genesis on the characteristics of TC track cannot be ignored. TCs that occurred father westward are more likely to move straight into the SCS region.     

FEATURES OF ENERGY BUDGET AND CONVERSION OF DEVELOPED AND UNDEVELOPED TROPICAL CYCLONE

With two cases of local tropical disturbances in both developed and undeveloped phases, contributions to the genesis and development by kinetic formation and transfer from divergent and nondivergent winds are studied using energy budget equations. Computations are done of conversion kinetic energy between the two types of winds. The result indicates that the subgrid scale effect is the principal source of kinetic energy for a tropical cyclone to grow into a typhoon; the cumulus convection plays a dominant role, in company of relatively weaker contributions on vdrious phases of the life cycle by convergence of fluxes of divergent and nondivergent winds as well as the formation of kinetic energy by the former wind. It is also suggested that the conversion of kinetic energy between the divergent and nondivergent winds C(K_x, K_ψ)is increasing with the development of disturbance mainly due to the contribution by C₁=f^▽Χ^▽ψ. The disturbance is shown in the distribution of C(K_x, K_ψ) to increase in a favorable anticyclonic outflow corresponding to the upper level where the conversion becomes negative in developing and mature phases while the wind velocity increases with enhanced conversion fr0m K_x to K_ψ the lower level in association with the growth of the disturbance. In addition,geopotential energy P converts to kinetic energy of the divergent wind in every stage from formation to mature of the disturbance by means of C(P, K_x), the maximum appearing on the middle and upper layers of the troposphere.The intensity of C(P, K_x) is consistently in phase with variation of C(K_x, K_ψ).     

NUMERICAL SIMULATION OF THE IMPACT OF LATENT HEAT FLUX ANOMALY IN THE TROPICAL WESTERN PACIFIC ON PRECIPITATION OVER SOUTH CHINA IN JUNES

Based on composite analysis and numerical simulations using a regional climate model （RegCM3）, this paper analyzed the impact of the LHF anomaly in the tropical western Pacific on the precipitation over the south of China in June. The results are as follows. （1） Correlation analysis shows that the SC precipitation in June is negatively correlated with the LHF of the tropical western Pacific in May and June, especially in May. The SC precipitation in June appears to negatively correlate with low-level relative vorticity in the abnormal area of LHF in the tropical western Pacific. （2） The LHF anomaly in the tropical western Pacific is a vital factor affecting the flood and drought of SC in June. A conceptual model goes like this： When the LHF in the tropical western Pacific is abnormally increased （decreased）, an anomalous cyclone （anticyclone） circulation is formed at the low-level troposphere to its northwest. As a result, an anomalous northeast （southwest） air flow affects the south of China, being disadvantageous （advantageous） to the transportation of water vapor to the region. Meanwhile, there is an anomalous anticyclone （cyclone） at the low-level troposphere and an anomalous cyclone （anticyclone） circulation at the high-level troposphere in the region, which is advantageous for downdraft （updraft） there. Therefore a virtual circulation forms updraft （downdraft） in the anomalous area of LHF and downdraft （updraft） in the south of China, which finally leads to the drought （flood） in the region.     

1986～1987年El Niño期间热带西太平洋及南海海气热量交换研究

文中根据热带西太平洋海气相互作用研究（ＴＯＧＡ）第１～５及第８航次和南海科学考察结果,对热带西太平洋和南海海气热量交换作了分析。结果表明：ＥｌＮｉｎｏ事件发生前,热带西太平洋及南海海气热量交换非常强烈;ＥｌＮｉｎｏ事件发生后,热带西太平洋及南海海气热量交换反而减弱。     

西北太平洋热带气旋路径异常偏折的分类特征

基于中国台风网CMA-STI热带气旋（TC）最佳路径资料,对1949—2016年西北太平洋TC路径发生异常偏折的地理位置进行K-means聚类分析,并将其分为五个区域。对各区TC路径异常偏折的频数、方向变化、周期及时间变率等特征进行分析。结果表明:(1)不同分区TC异常偏折高频月份不同,纬度较高区域主要发生在夏季,纬度较低区域则主要发生在秋季。(2)异常右折TC在发生偏折前移向主要为西北向,偏折后为北向;异常左折TC偏折前主要为北向,偏折后主要转为西北向。(3)西北太平洋TC异常偏折总频数存在准2~4年、准3~6年的年际变化周期,其长期变化趋势表现为20世纪80年代中期之前呈增加趋势,其后呈减少趋势, 低纬区域年变化与之最为相似,中高纬区域变化趋势不明显。（4）将研究区域按5 °×5 °进一步栅格化统计TC异常偏折频数的时间变率,发现其地理分布表现为中国沿海为正、台湾岛以东海域为负的变化特征。其中沿海的增加趋势主要由异常右折增加引起,台湾岛以东洋面的减弱趋势主要由异常左折的减少引起。(5)异常右折TC强度增强的高频中心主要位于菲律宾半岛以东洋面,次中心位于中国南海中部,而强度减弱位于台湾岛西南区域;异常左折TC强度增强的高频中心位于南海中部,强度减弱中心位于我国东南沿海。      

INFLUENCE OF THE INTERANNUAL VARIATION OF CROSS-EQUATORIAL FLOW ON TROPICAL CYCLOGENESIS OVER THE WESTERN NORTH PACIFIC

The influence of the interannual variation of cross-equatorial flow(CEF) on tropical cyclogenesis over the western North Pacific(WNP) is examined in this paper by using the tropical cyclone(TC) best track data from the Joint Typhoon Warning Center and the JRA-25 reanalysis dataset. The results showed that the number of TCs forming to the east of 140°E over the southeastern part of the western North Pacific(WNP) is in highly positive correlation with the variation of the CEF near 125° E and 150° E, i.e., the number of tropical cyclogeneses increases when the cross-equatorial flows are strong. Composite analyses showed that during the years of strong CEF, the variations of OLR, vertical wind shear between 200-850 h Pa, 850 h Pa relative vorticity and 200 h Pa divergence are favorable for tropical cyclogenesis to the east of 140°E over the tropical WNP, and vice versa. Moreover, it is also discussed from the view of barotropic energy conversion that during the years of strong CEF, an eastward-extended monsoon trough leads to the rapid growth of eddy kinetic energy over the eastern part of WNP, which is favorable for tropical cyclogenesis;but during the years of weak CEF, the monsoon trough is located westward in the western part of the WNP, consistent with the growth area of eddy kinetic energy. As a result, there are fewer TC geneses over the eastern part of WNP.Besides, the abrupt strengthening of a close-by CEF 2-4 days before tropical cyclogenesis may be the one of its triggers.     

西北太平洋热带气旋降水特征分析

利用1997—2006年GPCP(Global Precipitation Climatology Project)逐日卫星降水资料、上海台风研究所西北太平洋热带气旋资料,研究了近10年西北太平洋热带气旋降水的时空分布特征。发现整个西北太平洋区域多年平均TC(tropical cyclone)降水为175 mm,TC降水占总降水的比率为12%。年均TC降水场有两个极大值区域,分别位于菲律宾北部和菲律宾以东洋面。纬带平均的经向分布显示,总降水呈双峰分布,主、次峰值分别出现在6°N和35°N;而TC降水呈单峰分布,峰值出现在16°N。10年中TC降水以2004年最强;El Ni?o年TC降水在135°E以东偏多,而在南海中部和菲律宾至台湾等地区偏少;La Ni?a年TC降水在南海地区偏多,在菲律宾以东地区则显著偏少。