1998年青藏高原东侧边界层风场与长江暴雨洪水的关系

应用1998年6～8月四川省和重庆市探空资料,分析了青藏高原东侧大气边界层风场演变与长江上游暴雨和长江洪水的关系.结果表明:1998年夏季长江上游的暴雨天气与高原东侧成都边界层风场变化密切相关,当成都边界层为东北风时,高原东侧边界层维持气旋式偏东流场,长江上游未来产生暴雨等强对流天气;当为西南风等其他风向时,高原东侧边界层维持反气旋式偏南流场,未来是无降水天气;高原东侧边界层的动力激发作用是1998年长江上游暴雨产生的重要机制.并且,再次证明了西邻青藏高原的成都是长江上游天气变化关键点的观点.     

金沙江下游局地大气边界层风场变化特征

利用2008年在金沙江下游溪洛渡水电站坝区及向家坝水电站库区获得GPS低空探空资料以及同步地面观测资料,统计分析了坝区从地面开始到大气边界层2000 m高度四季不同高度的风场变化特征.结果表明:(1)春季溪洛渡坝区大气边界层以偏西风为主导风向,1500m高度层以下静风和小风出现频率大,是四个季节中地面静风、小风出现频率的最大值;(2)夏季地面静风、小风出现频率为四个季节中最小,夏季大气边界层中低层主要盛行西风和西北偏西风;(3)秋季溪洛渡坝区大气边界层中低层主要盛行偏西风,到高层则逐渐转变为偏北风;(4)冬季溪洛渡坝区大气边界层低空盛行以西风和西北偏西风为主导的偏西风;中高层主要风向是西风、西南偏西风、东风和东北偏东风;(5)溪洛渡坝区秋、冬季大气边界层西风、东北偏北风、东北偏东风风速最大值均出现在2000m高度层.     

高原季节转换时期大气环流变化特征

利用1961～ 2007年NCEP/NCAR的再分析逐日资料,分析高原主体上空大气环流的季节变化和受到高原影响的东亚大型环流系统的季节变化,以此证明本文得到的“高原普适性划分方法”的合理性.得到的初步结论概括如下：高原主体上空的位势高度、风场、高空温度、降水的季节变化和高原普适性季节划分方法划分的高原四季变化一致,高原南亚高压、副热带高压、副热带西风急流的三个特征指数季节变化和高原普适性季节划分方法划分的高原四季变化一致,这些结论都说明高原普适性季节划分方法划分的高原四季是合理的;风场季节率（500hPa、100hPa）显著区随高度升高向赤道靠近,风场季节率的变化主要和东亚季风的变化有关,大气环流系统季节率的显著说明了大气环流的季节变化,同时也证明了高原普适性季节划分方法的合理性.     

乌鲁木齐机场持续浓雾天气垂直风场特征分析

应用常规气象资料、机场地面气象观测资料、L波段探空风场资料以及边界层风廓线雷达资料,对2014—2016年乌鲁木齐机场持续浓雾天气的垂直风场结构及其演变特征进行分析。结果表明:(1)机场持续浓雾时高空天气形势主要有脊前型、脊区型、西风波动型和横槽型4类;(2)垂直风场结构主要有两种形态:Ⅰ型风场自上而下由西西北风层和边界层风场组成,Ⅱ型风场自上而下由西西北风层、空中东南风层和边界层风场组成;(3)西西北风层的下界高度在横槽型时最低、西风波动型时最高,空中东南风层在西风波动型和脊区型时厚度厚、风速大;(4)垂直风场演变在持续浓雾生消过程中有一定的规律,且中低空风场变化具有1～2 h的时间提前量,可在短临预报中发挥一定作用。     

丘陵地区大气边界层风廓线雷达适用性分析

本文利用2010年夏季福建省三明市开展的大气扩散实验资料,研究了大气边界层风廓线雷达在福建丘陵地区的适用性,并探讨了风廓线雷达探测的误差特征和修正方法。结果表明：大气边界层风廓线雷达水平风场的探测结果在300~2 000 m高度范围的偏差与高度和风速具有一定统计关系;通过与100 m气象铁塔水平风场资料对比,说明风廓线雷达对丘陵地区低层大气风场的探测具有一定局限性。经过修正的风廓线雷达探测结果可以较好地反映实验区域大气边界层水平风场的垂直结构。     

冬季东亚副热带急流与温带急流的比较分析：大尺度特征和瞬变扰动活动

使用ERA40再分析的月资料和逐日资料,从大尺度特征和瞬变扰动活动两个角度对冬季东亚副热带急流(EASJ)和东亚温带急流(EAPJ)进行了比较分析.结果表明,使用月资料分析的EASJ与EAPJ在高层风场上没有清晰的地理分界区,而使用逐日资料计算得到的冬季逐日急流发生数则以高原北部上空所处的纬度带为分界岭,存在两个急流中心集中区,分别对应于EASJ和EAPJ区域.通过分析东亚上空天气尺度瞬变扰动活动(STEA)表明,与强盛的冬季EASJ相伴随的是较弱的南支STEA,而与较弱的EAPJ相伴随的北支STEA却十分活跃,显示出EAPJ是与瞬变活动相伴而存的急流.进一步的诊断分析揭示了冬季东亚温带急流的两种主要异常模态,一种是EAPJ区域反气旋性/气旋性异常环流型,另一种是局地西风的减弱/增加.与第1种异常模态相关的北半球大尺度环流异常主要集中在欧亚中高纬地区,其形成受中高纬大气环流以及东亚上游大气环流异常的共同影响.当EAPJ局地西风减弱/增加时.EASJ东段至西太平洋上空的西风急流呈现出与之相反的变化型,北半球大气环流异常表现为大气遥相关的欧亚(EU)型.冬季EAPJ的两种异常模态还与东亚上空STEA异常密切联系,其中在北支STEA区域出现的瞬变异常以波列的形式沿STEA北支轴线传播到达东亚沿海上空,然后东传入洋面上空,而对于靠近STEA南支轴线的异常扰动活动则只能存在于东亚东部及其沿海上空的200 hPa层上.     

WRF模式中边界层参数化方案在藏东南复杂下垫面适用性研究

藏东南地区是青藏高原山地复杂下垫面的典型代表,其边界层大气过程异常复杂,给数值模拟和预报带来较大困难。大气边界层参数化方案的选取关系到能否正确模拟和预报局地大气过程。本研究采用中尺度模式WRF(Weather Research and Forecasting Model)对藏东南林芝地区对流和稳定边界层大气过程进行模拟,与2013年夏季"藏东南地区复杂下垫面地气交换观测实验"资料对比,研究ACM2,Boulac,M YJ,QNSE和YSU5种边界层参数化方案在青藏高原复杂下垫面的适用性。结果表明:对于水汽混合比垂直结构的模拟,Boulac和MYJ方案分别在模拟对流边界层和稳定边界层时能力最优。ACM 2方案最适宜藏东南复杂下垫面条件下的位温和风速垂直分布的模拟。各边界层参数化方案模拟对流边界层高度均较实际观测偏低,其中,QNSE方案模拟的边界层高度最接近观测。同一种边界层参数化方案对于夜间稳定边界层和正午对流边界层的模拟能力也不相同。该地区边界层风场受地形影响显著,风速较小,模拟的近地层风场较观测偏弱,MYJ和QNSE方案对近地层风场的模拟效果较好。     

大中地形对近地面层流场影响的数值模拟

本文对Mass,C.F.等的一层边界层原始方程诊断模式进行了适当修改,用于诊断大、中尺度地形对近地面风场的动力影响。结果表明:(1)它可用来诊断地形对地面气流的动力影响,具有计算量小和一定的模拟能力;(2)1月地面在高原东北侧陕甘宁地区形成反气旋环流中心和从高原北部35°N经高原东部边缘到高原东南角附近地面形成风向辐合线,可能主要受高原的动力影响所致。(3)由于祁连山对1月西风气流的影响,在它的附近形成中尺度气候系统。这些情况与资料分析结果比较一致。     

珠峰地区大气边界层结构的一次观测研究

利用2005年8月31日~9月5日中国科学院珠穆朗玛峰综合观测研究站的LAP3000风廓线仪的观测资料,分析了该地区气温日变化和大气边界层风廓线结构。结果表明,该地区1500 m以下大气边界层主要受高原山地地形及珠峰地区冰川环境的影响,冰川风可能是引起观测期间下午强风天气的主要原因;1500 m以上高空受西风气流影响程度增大,但东南风仍占有一定比例。     

青藏高原大气边界层结构特征研究综述

青藏高原对我国东部地区的天气和气候、亚洲季风乃至全球大气环流和天气气候都有重要影响,而高原大气边界层作为连接高原独特下垫面和自由大气的桥梁,在上述影响过程中扮演了重要作用。高原大气边界层观测资料的匮乏严重制约着青藏高原天气与气候研究。本文回顾了青藏高原大气边界层结构特征的研究历史,将这些成果进行了总结和分析,并对目前研究中存在的不足之处进行了探讨。     

Characteristics of the winter boundary layer over the African Plateau: 26 ° S

Characteristics of the winter boundary layer over the (elevation 1600 m) in the vicinity of Johannesburg, 26 ° S, 29 ° E, are described in relation to air pollution potential by means of doppler sounder observations and background climatological data. Regional mean winds for the 800 h Pa level show that the winter boundary layer is dominated by a cell of high pressure over the Limpopo River Valley to the northeast of Johannesburg. To the south of Johannesburg, westerly circumpolar flow is prevalent and encroaches onto the plateau during the passage of frontal perturbations. Doppler sounder wind and turbulence profiles, averaged for the months of August 1984 and June 1985, are presented to establish a boundary-layer climatology. Diurnally averaged doppler sounder profiles for both months revealed a very consistent convective/day — stable/night cycle in the very dry winter conditions. A sharp radiation inversion formed just after sunset up to the 150–200 m level and grew in depth to reach 300 m on average near sunrise. The inversion caused a reduction in frictional drag and the formation of nocturnal low level jet during westerly encroachment. A case study is evaluated to determine the detailed structure of the low level jet near Johannesburg. The thermal wind plays a role in the nocturnal acceleration; mechanisms for its development and maintenance are explored. Additional work is presented on the synoptic cycle and its influence on air pollution dispersion over the African Plateau.     

Seasonal Characteristics of Surface Radiation Fluxes on the East Rongbuk Glacier in the Mt. Everest Region

Ground-based measurements are essential for understanding alpine glacier dynamics, especially in remote regions where in-situ measurements are extremely limited. From 1 May to 22 July 2005 (the spring-summer period), and from 2 October 2007 to 20 January 2008 (the autumn-winter period), surface radiation as well as meteorological variables were measured over the accumulation zone on the East Rongbuk Glacier of Mt. Qomolangma/Everest at an elevation of 6560 m a.s.l. by using an automatic weather station (AWS). The results show that surface meteorological and radiative characteristics were controlled by two major synoptic circulation regimes: the southwesterly Indian monsoon regime in summer and the westerlies in winter. At the AWS site on the East Rongbuk Glacier, north or northwest winds prevailed with high wind speed (up to 35 m s-1 in January) in winter while south or southeast winds predominated after the onset of the southwesterly Indian monsoon with relatively low wind speed in summer. Intensity of incoming shortwave radiation was extremely high due to the high elevation, multiple reflections between the snow/ice surface and clouds, and the high reflective surrounding surface. These factors also caused the observed 10-min mean solar radiation fluxes around local noon to be frequently higher than the solar constant from May to July 2005. The mean surface albedo ranged from 0.72 during the spring-summer period to 0.69 during the autumn-winter period. The atmospheric incoming longwave radiation was greatly affected by the cloud condition and atmospheric moisture content. The overall impact of clouds on the net all-wave radiation balance was negative in the Mt. Qomolangma region. The daily mean net all-wave radiation was positive during the entire spring-summer period and mostly positive during the autumn-winter period except for a few overcast days. On monthly basis, the net all-wave radiation was always positive.     

2019年冬季北京海陀山局地环流特征及机理分析

海陀山作为北京冬(残)奥会的主要室外赛场之一,其复杂的地形对风场的精细化预报提出了严峻的挑战,亟需开展加密的风场观测提高对复杂地形下局地环流特征及其影响机理的认识,并为提升赛区精细化预报与服务提供数据支撑.基于2019年度海陀山观测试验,利用加密自动气象站、激光测风雷达、涡动相关仪、云高仪等多源数据,对海陀山风场的水平...     

利用折射指数推算大气纬圈平均风场方法

鉴于地转风、梯度风和平衡风各自计算风场的特点,该文利用COSMIC掩星折射指数资料,根据大气折射指数与大气密度、风场之间的关系,选用梯度风方程,建立了推算20~60 km中层大气纬圈平均风场的方法,分别与ECMWF提供的ERA-interim及NASA/GMAO提供的MERRA再分析风场资料对比验证。选用2007年1,4,7月和10月的COSMIC掩星折射指数数据,按照构建的方法计算了大气纬圈平均风场,并简单分析了大气纬圈平均纬向风随纬度、高度的变化特征及规律。计算风场与ECMWF及MERRA再分析风场资料变化规律基本一致,符合效果很好, 能够正确反映出纬向平均风场特性。1月及7月不同高度标准偏差、最大偏差随高度增加而增大,标准偏差最大约为6 m/s,最大偏差不超过11 m/s,沿纬度方向相关系数有减小的趋势,但不低于0.98,4月及10月偏差稍小,最大偏差不超过8 m/s。结果表明:利用COSMIC掩星折射指数资料通过梯度风方程计算风场,是获取中层大气20~60 km纬圈平均风场的一种有效方法。     

Diurnal and seasonal variation in surface wind at Sita Eliya, Sri Lanka

Summary Hourly measurements of surface winds at Sita Eliya (6° 58′ N, 80° 46′ E, 1860 m a.s.l.) located atop the North-South mountain ridge in Sri Lanka were analyzed to investigate the diurnal and seasonal variation in the wind climate. Surface winds are dominated by the monsoon regimes, with Northeasterlies from November to January, Southwesterlies from February to May and Westerlies and Northwesterlies from June to October. Through most of the year, the average wind speed is around 6–8 m/s. However from June to August, it is around 10–14 m/s. Wind in June is gusty due the location of the low-level Easterly jet over Sri Lanka. The wind undergoes a reversal in both zonal and meridional directions in March and November coincident with the migration of the Inter-Tropical Convergence Zone. Notwithstanding the period from May to September being designated as the Southwest monsoon, the wind is from West, South-West-West and North-North-West. During the Southwest monsoon, wind speed during the night is nearly as high as that during the day. This anomalous diurnal variation in wind speeds may be related to orographic influences. The high wind speeds at Sita Eliya, in conjunction with the moderate diurnal and seasonal variability in wind speed, is suitable for wind-energy generation. Received January 2, 2001 Revised May 26, 2001     

The feasibility of estimating large-scale surface wind fields for the summer MONEX using cloud motion and ship data

Cloud motion data were compared to ship observations over the Indian Ocean during the summer monsoon, 1 May to 31 July 1979, with the objective of using the cloud data for estimating surface wind and ultimately the wind stress on the ocean. The cloud-ship comparison indicated that the cloud motions could be used to estimate surface winds within reasonable accuracy bounds, 2.6 m s^-1 r.m.s. speeds and 22° to 44° r.m.s. directions (22° r.m.s. for winds < 10 m s^-1). A body of statistics is presented which can be used to construct an empirical boundary layer with the eventual goal of producing a stress analysis for the summer MONEX from cloud motion data.     

南亚高压上下高原时间及其与高原季风建立早晚的关系

本文利用1948—2013年NCEP/NCAR逐日再分析资料,定义了南亚高压动态特征指数,讨论了南亚高压上下高原的时间以及与高原季风建立早晚的关系。研究表明,南亚高压北界位置在4月初开始北移,5月迅速北抬,最北可达到55°N,9月开始南撤,西伸脊点在5—10月移动较稳定,5—7月向西移动到青藏高原上空,8—10月向东移动撤离高原,11月—次年4月东西摆动剧烈。南亚高压初上高原大致为6月第3候(33候),而撤离约为10月第4候(58候)。南亚高压移上高原的时间较高原夏季风建立晚73 d左右。南亚高压撤离高原时间较高原冬季风建立约早5 d。高原夏季风的建立和南亚高压初上高原是青藏高原热力作用在不同阶段的结果,反映在了高原的高低层上。     

泰山酸雨特征及影响因素分析

利用2006—2015年泰山气象站的降水pH、电导率、降水量和风向风速资料,统计分析了泰山酸雨特征和变化趋势,探讨了降水量和风向风速对酸雨的影响。结果表明,泰山降水年均pH变化范围为4.31～4.99,酸雨发生频率达到69.3%;pH随降水量的增加而趋于5.60（中性）;5月至次年1月的月均pH与月平均过程降水量的变化趋势一致;月均电导率与月平均过程降水量的变化趋势相反。泰山降水期间盛行西南风,在南风和东北风条件下,酸雨出现频率最高且酸性最强,这主要是风速风向因素和人为排放源分布共同导致的。近10 a泰山降水酸性程度有所减弱,酸雨频率明显下降,表明近年来酸雨污染情况有所改善,有利于保护泰山生态环境。     

珠峰地区登山气象条件分析

利用珠峰大本营的地面和探空资料,详细分析了珠峰地区各高度层的气温、气压、风向风速以及湿度等气象要素,浅析了4~5月登山气象条件,并得出初步结论。