陶诗言先生在中国暴雨发生条件和机制研究中的贡献   总被引：5，自引：1，他引：4  

丁一汇 《大气科学》2014,38(4):616-626

作者在1998年庆贺陶诗言先生八十华诞的文集中曾专题阐述和评价了陶先生对中国暴雨研究的贡献。 至今十五年过去了,陶诗言先生虽已于2012年仙逝,但其深邃的科学思想依然闪烁着智慧的火花。他在中国暴雨研究中留下的宝贵遗产不但深刻影响过去和现代两代人的暴雨研究和业务发展,而且也将继续影响将来的中国暴雨研究。本文是对陶诗言先生在中国暴雨的研究中所作的贡献并结合现代研究的成果作进一步介绍和评价。主要集中在暴雨发生的动力和热力条件与机理方面。全文内容包括六个方面:（1）季节突变对中国梅雨爆发的影响;（2）暴雨发生的多尺度相互作用;（3）暖湿季风输送带对北方大暴雨的影响;（4）高空急流对暴雨的作用;（5）暴雨和强对流发生的物理条件;（6）地形对暴雨的作用  相似文献   

西北太平洋海域风浪、涌浪、混合浪波浪能资源特征   总被引：1，自引：0，他引：1  

郑崇伟  游小宝  陈晓斌  李燕 《气象科学》2014,34(4):408-413

用ECMWF的ERA-40海浪再分析资料,应用波浪能流密度计算方法,对西北太平洋海域的风浪能、涌浪能、混合浪能展开研究。结果表明:(1)波浪能流密度呈现出显著季节性差异。混合浪能流密度表现为冬高夏低;春、夏、秋季的涌浪能流密度明显大于风浪能流密度,冬季相反;(2)混合浪能流密度的大值区主要分布于阿留申群岛附近海域,高值中心可达60 kW/m以上;近海的大值区主要分布于琉球群岛—巴士海峡—传统的南海大风区一带,年平均值在4 kW/m以上,南海北部可达12 kW/m以上;(3)黄渤海的涌浪和混合浪能流密度峰值出现在8—9月,波谷出现在6月。风浪能流密度峰值出现在11月—次年3月,波谷出现在6—8月,均呈现双峰型月变化特征。东海、南海北部、南海中南部海域能流密度的月变化特征相似,都为双峰型,12月—次年4月的能流密度整体较高,波峰出现在12月,波谷出现在5—7月;(4)2 kW/m以上混合浪能流密度出现的频率较高,近海低于大洋;(5)0.5 m以上有效波高出现的频率都非常高,中国近海稍低于大洋;(6)涌浪能流密度的稳定性明显好于风浪能流密度;大洋的能流密度稳定性明显强于近岸。1月份能流密度的稳定性最好,4月和7月次之,10月的稳定性最差。  相似文献   

南海温度锋的分布特征及季节变化     

朱凤芹  谢玲玲  成印河 《海洋与湖沼》2014,45(4):695-702

利用50a(1950—2007年)的SODA(Simple Ocean Data Assimilation)数据分析了南海上层温度锋分布特征以及季节变化规律。结果表明:受季风、太阳辐照以及诸多因素影响,温度锋季节变化明显,锋面结构复杂。冬季,温度锋基本沿陆架分布,存在于南海北部海区,从台湾海峡一直延伸到北部湾,发育比较显著;春季,主要出现在南海北部海区、北部湾、越南东部海岸,分布比较广泛;夏季温度锋出现概率增加,出现区域扩大,越南东部出现大面积温度锋;秋季南海中西部海域存在大面积的温度锋。  相似文献   

Seasonal and mesoscale variability of primary production in the deep winter-mixing region of the NW Mediterranean     

《Deep Sea Research Part I: Oceanographic Research Papers》2014

  相似文献   

A global satellite view of the seasonal distribution of mineral dust and its correlation with atmospheric circulation     

《Dynamics of Atmospheres and Oceans》2014

Aerosols make a considerable contribution to the climate system through their radiative and cloud condensation nuclei effects, which underlines the need for understanding the origin of aerosols and their transport pathways. Seasonal distribution of mineral dust around the globe and its correlation with atmospheric circulation is investigated using satellite data, and meteorological data from ECMWF. The most important sources of dust are located in North Africa, the Middle East and Southwest Asia with an observed summer maximum, and East Asia with a spring peak. Maximum dust activity over North Africa and the Middle East in summer is attributed to dry convection associated with the summertime low-pressure system, while unstable weather and dry conditions are responsible for the spring peak in dust emission in East Asia. Intercontinental transport of mineral dust by atmospheric circulation has been observed, including trans-Atlantic transport of North African dust, trans-Pacific transport of Asian dust, and transport of dust from the Middle East across the Indian Ocean. The extent of African dust over the Atlantic Ocean and its latitudinal variation with season is related to the large-scale atmospheric circulation, including seasonal changes in the position of the intertropical convergence zone (ITCZ) and variation of wind patterns. North African aerosols extend over longer distances across the North Atlantic in summer because of greater dust emission, an intensified easterly low level jet (LLJ) and strengthening of the Azores-Bermuda anticyclonic circulation. Transport of East Asian aerosol is facilitated by the existence of a LLJ that extends from East Asia to the west coast of North America.  相似文献   

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刘根友  郝晓光  陈晓峰  孙保琪  彭碧波  周旭华  柳林涛  胡小刚 《大地测量与地球动力学》2007,27(5):115-118

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东亚-太平洋地区环流场和热力场由冬向夏转换的过程特征及其可能机制   总被引：3，自引：0，他引：3  

池艳珍  刘丹妮  何金海  祁莉 《高原气象》2013,32(4)

利用NCEP/NCAR逐日再分析资料和青藏高原逐日视热源资料,分析了东亚 太平洋地区对流层热力场和环流场的季节特征.结果表明,东亚-太平洋热力场上呈现出冬、夏半年反向的特征,冬半年热力格局为“西冷东暖”,夏半年则转为“西暖东冷”,冬半年向夏半年的过渡发生在3月底4月初,相应地,我国东部上空视热源也从冷却转为加热.热力场季节转换的同时,对流层各层环流形势也发生了调整:低层大陆冷高压减弱、东移,太平洋副热带高压显著西伸,形成东亚-西太平洋35°N以南一致的南风区;中层西风带发生了长波调整,由冬季“三槽型”向夏季“四槽型”过渡,西风急流减弱、北移;高层反气旋中心史替,我国上空偏南风由偏北风替代.环流的演变自低层向高层推进,下垫面感热加热的季节变化引起了低层环流的调整以及上升运动的发展,与上升运动相伴的凝结潜热释放则增强了东亚上空的热源,进一步加强了“西暖东冷”的热力格局,从而推进中高层环流的演变.环流调整的时间与东亚副热带季风雨带建立的时间一致,因此,由热力场季节变化引起的对流层环流形势的调整可看成是东亚副热带夏季风环流型的建立过程.  相似文献   

Intensified Eastward and Northward Propagation of Tropical Intraseasonal Oscillation over the Equatorial Indian Ocean in a Global Warming Scenario     

YANG Jing  BAO Qing  WANG Xiaocong 《大气科学进展》2013,30(1):167-174

Northward propagation in summer and eastward propagation in winter are two distinguished features of tropical intraseasonal oscillation(TISO) over the equatorial Indian Ocean.According to numerical modeling results,under a global warming scenario,both propagations were intensified.The enhanced northward propagation in summer can be attributed to the enhanced atmosphere-ocean interaction and the strengthened mean southerly wind;and the intensified eastward propagation in winter is associated with the enhanced convection-wind coupling process and the strengthened equatorial Kevin wave.Future changes of TISO propagations need to be explored in more climate models.  相似文献   

接地电阻随季节及天气过程变化规律分析     

王孝波  曾昌军  邓春林  但建茹  王建国 《气象科学》2013,33(6):648-652

为了解框架结构建筑物基础接地电阻的季节变化特征及天气过程对其变化的影响,分析了2010年广州从化气象局框架建筑物基础接地电阻和相关气象要素的自动气象站观测资料。从季节变化特征来看,框架结构接地电阻相对较为稳定,月平均值2月最大为0.78 Ω,9月份最小为0.57 Ω,全年变化最大值约为0.21 Ω。统计季节变化曲线和暴雨过程发现,接地体电阻与1.5 m土壤温度和1.0 m土壤含水量呈现明显的负相关,接地电阻减小值与暴雨的强度无明显的相关性。文中还对较长时间无降水的干旱过程进行了分析,结果表明：干旱时框架结构接地电阻值有明显的上升趋势,尤其在夏季,干旱对接地电阻影响较大。  相似文献   

Dynamics of seasonal recharge beneath a semiarid vegetation on the gnangara mound,Western Australia     

M. L. Sharma  M. Bari  J. Byrne 《水文研究》1991,5(4):383-398

To estimate seasonal changes in recharge to the underlying sandy aquifer, the soil water dynamics of the unsaturated zone was monitored down to a depth of 20 m over a period of three years (1985 to 1987). The measurements were made by a neutron probe at eight locations beneath a native vegetation in a semiarid region, Western Australia, receiving precipitation of 775 mm yr^?1. A relatively simple method, based on the analyses of sequentially measured soil water profiles involving utilization of zero flux plane in the unsaturated zone, is presented and used to compute seasonal recharge rates. Drainage fluxes (recharge rates) below two specified depths were estimated. These were: R₁ (water flux at a depth of 10 m, just below the maximum rooting depth) and R₂ (water flux at a depth of 18 m, just above the water table). These two estimates were significantly different both on a seasonal and annual basis, but their cumulative values for the three year period were very similar. While the annual precipitation varied from 525 to 850 mm yr^?1, the corresponding spatially averaged R₁ varied from 34 to 149 mm yr^?1, and R₂ varied from 65 to 80 mm yr^?1. A significant difference in recharge between the upslope and downslope positions on a hillslope was ascribed to differences in vegetation density of the understorey and differences in hydraulic properties of subsoils. For the three year period, the average R₁ and R₂ were 13 per cent and 10 per cent of the precipitation respectively. These values compare favourably with a long-term estimate based on an environmental tracer technique.  相似文献