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1.
The First Observed Cloud Echoes and Microphysical Parameter Retrievals by China's 94-GHz Cloud Radar 总被引:1,自引:0,他引:1 
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下载免费PDF全文 WU Juxiu WEI Ming HANG Xin ZHOU Jie ZHANG Peichang LI Nan 《Acta Meteorologica Sinica》2014,28(3):430-443
By using the cloud echoes first successfully observed by China's indigenous 94-GHz SKY cloud radar, the macrostructure and microphysical properties of drizzling stratocumulus clouds in Anhui Province on 8 June2013 are analyzed, and the detection capability of this cloud radar is discussed. The results are as follows.(1) The cloud radar is able to observe the time-varying macroscopic and microphysical parameters of clouds,and it can reveal the microscopic structure and small-scale changes of clouds.(2) The velocity spectral width of cloud droplets is small, but the spectral width of the cloud containing both cloud droplets and drizzle is large. When the spectral width is more than 0.4 m s-1, the radar reflectivity factor is larger(over –10 dBZ).(3) The radar's sensitivity is comparatively higher because the minimum radar reflectivity factor is about–35 dBZ in this experiment, which exceeds the threshold for detecting the linear depolarized ratio(LDR) of stratocumulus(commonly –11 to –14 dBZ; decreases with increasing turbulence).(4) After distinguishing of cloud droplets from drizzle, cloud liquid water content and particle effective radius are retrieved. The liquid water content of drizzle is lower than that of cloud droplets at the same radar reflectivity factor. 相似文献
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不同于体扫雷达探测降水系统,垂直指向雷达可探测降水云中粒子垂直演变的微物理过程。C波段调频连续波垂直指向雷达 (C-FMCW) 采用收发分置天线,数据垂直分辨率达15~30 m,时间分辨率达2~3 s,利用其2013年6—8月在安徽定远探测数据对降水云垂直结构特征及亮带中融化微物理过程进行研究。6次降水过程共计46 h中的39.1%数据具有清晰的亮带结构特征,期间降水占地面总降水量的15%;江淮雨季层状云、对流云和混合性降水系统中均出现零度层亮带,层状云中亮带长时间维持,对流降水系统移出后减弱阶段的亮带结构稳定,混合降水系统中的对流扰动加强冲破了亮带结构。以融化层中最大回波强度Zp所在高度进行融化层的粒子碰并增长和破碎减弱分层分析,上半层融化过程主要表现为碰并增长,下半层则是粒子破碎减弱。剔除了介电常数、下降速度引起的粒子浓度改变影响后,层状云和对流降水后期的回波强度加强表明融化增长程度接近,后者略强,混合降水云的融化增长最强。 相似文献
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为了加强对青藏高原深对流云垂直结构的深入认识,利用TRMM、CloudSat和Aqua多源卫星观测资料及地基垂直指向雷达(C波段调频连续波雷达和KA波段毫米波云雷达)资料,对第三次青藏高原大气科学试验期间2014年7月9日13-16时(北京时)发生在那曲气象站附近的深厚强对流云和那曲气象站以西100 km左右的深厚弱对流云的垂直结构特征进行了分析,得到的结果如下:(1)深厚强对流云和深厚弱对流云的水平尺度均较小(10-20 km),垂直发展高度较高(15-16 km,均指海拔高度);深厚强对流云在0℃层以下雷达反射率因子递增非常快,表明对流云内固态降水粒子下落至0℃层以下后融化过程有很重要的作用;在对流减弱阶段有明显的0℃层亮带出现,亮带位于5.5 km左右(距地1 km);(2)对比TRMM测雨雷达和C波段调频连续波雷达观测到的雷达反射率因子,发现TRMM测雨雷达在11 km以下存在高估;(3)深对流云主要为冰相云,云内10 km以上主要是丰富小冰粒子,而10 km以下是较少的大冰晶粒子;深厚强对流云和深厚弱对流云的微物理过程都主要包括混合相过程和冰化过程,混合相过程分为两种:一种是-25℃(深厚强对流云)或-29℃(深厚弱对流云)高度以下以凇附增长为主,另一种是该高度以上主要以冰晶聚合、凝华增长为主,该过程冰晶粒子有效半径增长较快。这些空基和地基的观测证据进一步揭示了青藏高原深对流云的垂直结构特征,为模式模拟青藏高原深对流云的检验提供了依据。 相似文献
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利用2008年9月—2016年8月的CloudSat卫星资料对发生在我国低纬度陆地区域(5°~36.5°N, 78°~124°E)的卷云物理特征进行统计分析,并分别讨论东部沿海、中部、西部3个子区域的卷云物理特征的季节变化。结果表明:卷云的整层发生率西部地区整体低于中部与东部沿海地区。3个子区域整层发生率均在夏季最高、冬季最低。卷云的主要发生高度在5.04~18.71 km,垂直分布中卷云发生率的最大值出现在春季中部地区,为15.34%,高度为9.83 km。冰水路径最大值出现在夏季的东部沿海,液水路径最大值在秋季的西部地区。冰水含量、冰粒数浓度、冰粒有效半径的主要分布高度与卷云的发生高度一致,液水含量、液滴数浓度、液滴有效半径的主要分布高度在5.04~9.35 km。3个子区域卷云冰水含量、冰粒数浓度、冰粒有效半径垂直分布中大多集中在中上部;液水含量垂直分布主要集中在分布高度的中下部。四季卷云雷达反射率因子的最大值在-19.89~-16.78 dBZ,分布高度在7.19~10.55 km。 相似文献
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利用不同形状冰晶的散射特性,获得了非球形冰晶云的94/220 GHz测云雷达双波长比,探讨了非球形冰晶云的双波长比与云内微物理参数的关系,分析了衰减前后的星载雷达反射率因子及双波长比的垂直廓线。结果表明:(1)双波长比可以反映小到0.1 mm中值尺度的冰粒子,对粒子总数、谱的形状参数不敏感,对粒子大小、形状、云衰减较敏感。(2)雷达灵敏度一定时,星载雷达可测云厚与雷达波长、冰含水量(IWC)的垂直分布、云厚及衰减有关;没有进行衰减订正时,双波长比和衰减有关,冰含水量越大,波长越短,衰减越大,双波长比最大值与可探测云厚有关。两部雷达可探测冰含水量为0.001—0.1 g/m3、厚2 km的冰云;当云厚5 km、冰含水量垂直分布在0.001—0.2 g/m3时,云厚的94%基本可以被220 GHz云雷达探测到。(3)如果两部雷达气象方程中用水的介电因子,测量回波强度应进行介电因子的订正后再计算双波长比。 相似文献
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河北春季一次飞机人工增雪的综合分析 总被引:1,自引:0,他引:1
2013年4月19日,河北省人工影响天气办公室在河北中南部地区根据云系特点首次采用多层次水平催化和垂直验证的方式对层状云进行人工催化和探测。本文利用机载仪器所取得的飞机探测资料,结合实时天气、卫星、雷达、探空和雨量观测资料,分析了河北春季层状云增雪作业的技术指标,探讨了航测微物理参量和卫星、雷达、探空等资料在作业中的应用。结果表明:云在发展期雷达回波由15 dBZ逐步上升到25-35 dBZ,卫星反演的云顶高度、云顶温度、有效粒子半径、光学厚度等都有增加;云在中后期有效粒子半径、光学厚度、液水路径迅速下降,雷达回波同时减弱。在高度3 177-5 723 m之间过冷云滴达100-700个/cm^3,含水量在0.01 g·m^-3左右,最大0.081 g·m^-3,云粒子主要在此增长,形成降水粒子,该区间适宜催化。作业后,影响区内云体发展,雷达回波增强,出现35 dBZ强回波,且强回波中心扩大;卫星反演的云顶高度、光学厚度等比对比区有明显增加。 相似文献
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选取2004—2012年广东省12个大冰雹风暴单体为样本,利用多普勒天气雷达资料,计算了最大反射率因子及其高度等多个雷达参数,分析了三体散射、旁瓣回波和环境温度层上回波特征以及大冰雹与非冰雹风暴单体间的反射率因子垂直廓线差异。结果表明:大冰雹风暴单体发展均非常旺盛,最大反射因子多超过65 dBZ,对应高度几乎都达到5 km。除受周围大范围雷达回波影响外,大冰雹风暴单体均观测到了三体散射或旁瓣回波特征,并具有一定的预报提前量;在0℃和-20℃层高度上的最大反射率因子均超过54 dBZ。大冰雹风暴单体与非冰雹风暴单体相比,低层回波迅速增加,强核心区垂直伸展更深厚,回波垂直递减率更小。 相似文献
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Millimeter-wavelength radar has proved to be an effective instrument for cloud observation and research. In this study, 8-mm-wavelength cloud radar (MMCR) with Doppler and polarization capabilities was used to investigate cloud dynamics in China for the first time. Its design, system specifications, calibration, and application in measuring clouds associated with typhoon are discussed in this article. The cloud radar measurements of radar reflectivity (Z), Doppler velocity (Vr), velocity spectrum width (Sw) and the depolar-ization ratio (LDR) at vertical incidence were used to analyze the microphysical and dynamic processes of the cloud system and precipitation associated with Typhoon Nuri, which occurred in southern China in August 2008. The results show the reflectivity observed using MMCR to be consistent with the echo height and the melting-layer location data obtained by the nearby China S-band new-generation weather radar (SA), but the Ka-band MMCR provided more detailed structural information about clouds and weak precipitation data than did the SA radar. The variation of radar reflectivity and LDR in vertical structure reveals the transformation of particle phase from ice to water. The vertical velocity and velocity spectrum width of MMCR observations indicate an updraft and strong turbulence in the stratiform cloud layer. MMCR provides a valuable new technology for meteorological research in China. 相似文献
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结合2014年7—8月第三次青藏高原大气科学试验获得的毫米波雷达资料与探空温度资料,利用模糊逻辑法反演了西藏那曲地区夏季云中水成物的相态并对其分布特征开展了研究。首先,分析了层积云、雨层云以及深对流云的典型个例,发现三类云反射率因子、多普勒速度、速度谱宽以及退偏振因子垂直分布均有较大差别,相应的云中水凝物的回波特征与相态分布差别也较大。其次,研究了液相、混合相和冰相云层的云雷达探测特征,发现液相云层在0℃层以下的暖云层和0℃层以上的过冷水云层均具有反射率因子高值中心,混合云层的反射率因子高值中心随高度上升变化不大,冰云层的反射率因子高值主要集中在6 km以上,且随高度上升而趋于集中;三种相态云层出现频率高值分别集中在地面以上1、2~3、3~4 km高度层;液相云层在上午出现频率最高,混合相云层高频率发生在下午,冰相云层在晚上的出现频率最高。三种相态云层出现在上午的高度与下午和晚上相比较低,出现在晚上的高度范围最大;液相云层厚度一般小于0.3 km,冰相云层云顶位于9 km左右高度层时平均厚度最大,中云内的混合相和冰相厚度变化较小。 相似文献
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地基云雷达是云的重要探测手段,但随着运行时间的增加,雷达发射机、接收器等参数的变化,会使观测数据产生漂移偏差,从而对云物理特性的反演产生显著影响,因此云雷达数据的校准是一个重要的基础问题。针对KAZR(Ka Band Zenith Radar,K波段云雷达)云雷达特征,本文在Pavlos等提出的雷达数据校准方法基础上进行改进,优化了对弱云和降水的信号识别,利用CloudSat星载雷达观测的反射率因子,气体衰减校正等数据,对兰州大学半干旱气候环境监测站(Semi Arid Climate and Environment Observatory of Lanzhou University,SACOL)KAZR云雷达2013年8月至2017年5月反射率因子数据进行了校准,建立了KAZR雷达反射率因子46个月的历史资料校准数据库,并对校准周期的变化进行了对比分析。校准数据库的建立对SACOL站云的长期观测研究具有重要意义,同时为不同波段地基雷达的对比增加了可行性。 相似文献
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利用2017—2019年中国气象局大气探测试验基地Ka波段云雷达资料,结合地面自动气象站、激光云高仪资料,从强度、速度、线性退极化比以及晴空回波高度等方面,分析晴空回波垂直结构和变化特征。基于激光和微波对粒子半径和数密度散射的差异,区分云和晴空回波。结果表明:Ka波段云雷达探测到的晴空回波在边界层主要包含层状湍流回波和点状昆虫回波,且回波顶高在3000 m以内。晴空回波强度和高度具有明显的季节和日变化特征,冬季回波顶高较低,夏季回波顶高较高,与地面气温具有很好的相关性,每年的1,2,11,12月几乎没有晴空回波,而7月和8月回波顶平均高度最高。晴空回波反射率因子为-40~-15 dBZ,其中层状湍流回波反射率因子概率密度峰值处反射率因子为-35 dBZ,点状昆虫回波反射率因子概率密度峰值处反射率因子为-30 dBZ。晴空回波垂直移动速度为-1.5~+0.5 m·s-1,整体呈下沉运动。层状湍流回波线性退极化比较点状昆虫回波稍大,一般为-10~-5 dB,点状昆虫回波线性退极化比一般为-15~-8 dB。 相似文献
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In order to investigate the physical structure characteristics of the clouds and precipitation over the Tianshan Mountains in summer, the Urumqi Institute of Desert Meteorology of China Meteorological Administration (CMA) carried out an atmospheric detection experiment in Bayanbulak from 1st to 31st August 2012 by means of a wind-profiling radar and a Doppler weather radar. Using the radar observation data, this paper analyzes the dynamic, thermodynamic, radar echo intensity and macro-micro structure characteristics of the 2–3 August precipitation process. The results show that: (1) The radar echo intensity of this rainfall process changes within 5–38 dBZ, and the precipitation cloud system is under the height of 6500 m, with notable 0 °C level echo bright band between 1200 m and 2000 m height. NCEP analysis data shows that the cloud top temperature ranges from ?25 °C to ?32 °C. These indicate the features of typical stratiform cold cloud precipitation. (2) Atmospheric motion during the precipitation process presents the multi-layer structure with wind velocity varying within the range of 3.0–8.0 m/s. The temperature advection is presented with the vertical structure distribution of “cold-warm-cold”, which indicates relative stability of the atmospheric stratification. (3) By retrieving and analyzing the raindrop size distributions below 0 °C level bright band within 600–1200 m height, when the precipitation evolve from early stage to its peak stage, the concentration of the tiny particle zone (D?≤?2.5 mm) changes a little while the concentration of the medium particle zone (2.5?<?D?≤?4 mm) and the concentration of the large particle(D?>?4 mm) increase considerably; but after peak stage the concentration in the medium particle zone and the concentration in the large particle zone decline first, then the concentration in the tiny particle zone reduces. (4) Raindrop size distribution data is used to calculate the precipitation intensity and the liquid water content, whose spatial-temporal variation characteristics are the same. During peak stage of the precipitation, the instantaneous precipitation intensity reaches 5.0 mm/h, and the liquid water content reaches 0.35 g/m3. This study would help deepen the understanding on the physical structure of the clouds and precipitation over the Tianshan Mountains in summer, and also provide some scientific basis for cloud seeding operation over this area. 相似文献
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The cloud phase composition of cold clouds in the Antarctic
atmosphere is explored using data from the Moderate Resolution Imaging
Spectroradiometer (MODIS) and Cloud-Aerosol Lidar with Orthogonal Polarization
(CALIOP) instruments for the period 2000--2006. We used the averaged fraction
of liquid-phase clouds out of the total cloud amount at the cloud tops since
the value is comparable in the two measurements. MODIS data for the winter
months (June, July, and August) reveal liquid cloud fraction out of the total
cloud amount significantly decreases with decreasing cloud-top temperature
below 0oC. In addition, the CALIOP vertical profiles show that below the
ice clouds, low-lying liquid clouds are distributed over ~20% of the
area. With increasing latitude, the liquid cloud fraction decreases as a
function of the local temperature. The MODIS-observed relation between the
cloud-top liquid fraction and cloud-top temperature is then applied to evaluate
the cloud phase parameterization in climate models, in which condensed cloud
water is repartitioned between liquid water and ice on the basis of the grid
point temperature. It is found that models assuming overly high cut-offs
(》-40oC) for the separation of ice clouds from mixed-phase clouds may
significantly underestimate the liquid cloud fraction in the winter Antarctic
atmosphere. Correction of the bias in the liquid cloud fraction would serve to
reduce the large uncertainty in cloud radiative effects. 相似文献
16.
该文提出了一种基于雷达体扫资料的任意基线雷达反射率因子垂直剖面的生成算法。在计算雷达反射率因子垂直剖面上的格点在雷达极坐标中的仰角、方位和斜距位置后, 采用径向、方位上的最近邻居和垂直方向的线性内插相结合的客观分析方法得到格点上的反射率因子分析值。在垂直线性内插时分别用dBZ值和Z值 (单位: mm6/m3) 进行插值。结果表明:用该方法得到的雷达反射率因子垂直剖面从回波强度和空间位置来看都是合理的; 当采用垂直线性内插时, 用dBZ值插值比用Z值插值得到的雷达反射率因子垂直剖面在空间分布上更连续, 反射率因子分析值总体上更接近观测值; 低仰角的插值效果比高仰角的好。 相似文献
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基于2014—2015年5—9月西藏那曲地区多普勒天气雷达数据,结合地闪观测数据,识别雷暴单体样本,统计分析了地闪位置附近的雷达回波分布特征,并研究了高原雷暴的雷达参量与地闪频次的相关关系。结果表明:那曲地区地闪发生位置附近的雷达最大反射率因子呈正态分布,峰值分布区间集中于34~41 dBZ。发生地闪位置附近的20 dBZ回波顶主要集中于11~15 km高度,30 dBZ回波顶高分布的峰值区间则为8.5~12 km。分析表明:表征局地雷暴对流发展强度的雷达参量与地闪频次之间一对一的相关关系较差,但相关性随地闪频次增加而增强。基于雷达参量分段统计得到的对应分段平均地闪频次与雷达参量之间表现出较强相关关系,体现了宏观上闪电活动强度与雷暴发展强度之间的正向关系。其中,基于原始数值进行区间划分的强回波(组合反射率因子不小于30 dBZ)面积与平均地闪频次的线性相关系数达0.75,基于对数数值区间划分的7~11 km累积可降冰含量的对数值和地闪频次的线性相关系数达0.95。文中对比了多个雷达参量和地闪频次线性拟合与幂函数拟合结果,整体上幂函数拟合略好于线性拟合。 相似文献
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A. A. Sin’kevich V. B. Popov I. A. Tarabukin E. V. Dorofeev Yu. A. Dovgalyuk N. E. Veremei Yu. P. Mikhailovskii V. S. Snegurov A. V. Snegurov 《Russian Meteorology and Hydrology》2018,43(8):506-515
The results of investigation of convective cloud merging observed near Saint Petersburg are presented. Data obtained with a set of remote sensing instruments (radar, radiometer, and lightning location system) were analyzed. Rain gage network data are used. Clouds simulation is performed using a 1.5-dimensional nonstationary model. A method to calibrate the radar measurements to obtain precipitation characteristics using rain gage network data is developed. According to radar data, a 2-km increase in the cloud top height was observed after Cu merging, the maximum reflectivity of clouds increased at 10 dBZ, maximum rain intensity and rain flux increased by about two times. The increase in rainfall intensity is also corroborated by rain gage observations and numerical simulations. An increase in the intensity of lightning discharges during the merging is registered. 相似文献
19.
毫米波测云雷达在降雪观测中的应用初步分析 总被引:2,自引:0,他引:2
本文利用毫米波云雷达联合称重式雨量计、气球探空和S波段天气雷达在北京对2015年11月三次降雪进行了观测,以2015年11月22~23日降雪过程为例,主要从降雪系统的宏观结构特征、微物理变化以及毫米波雷达在降雪探测中电磁波衰减情况、雪粒子含水量和地面降雪量估测几方面进行初步分析。结果表明:(1)毫米波云雷达具有高时空分辨率,能对降雪系统进行精细化探测,在降雪系统发展最旺盛的阶段能够通过反射率(Z)、退极化比(LDR)和径向速度(V)初步判断出云中是否含有过冷液滴;(2)降雪回波强度最大值能反映整层云系中含水量最大的区域,当最大值Z大于20 dBZ时,最大值的大小、最大值持续时间、最大值出现的高度与地面降水量成正相关,速度最大值表示云中粒子上升最大速度(速度为正时)或者粒子下落的最小速度(速度为负时),主要分布在-0.5~2 m s?1,速度最小值表示粒子下落的最大速度,主要在-3~-1 m s?1;(3)随着高度增加反射率的垂直廓线会出现多个峰值,这是由于不同高度层风速分布不均造成的,降雪回波这种特点比降雨回波更明显;(4)对比Ka与S波段雷达反射率可知,两雷达反射率平均差值小于2.5 dBZ,Ka波段反射率略大S波段雷达反射率;(5)降雪量反演与地面降雪量仪数据对比,逐小时降雪量反演精度为20.38%,累计降雪量反演误差为6.58%,24小时累计降雪量绝对误差为1.9 mm,说明云雷达估算累计降雪量具有较高的可行性,能够很准确的反映地面实际降雪情况,当降雪系统发展旺盛时,雪粒子含水量分布在0.05~0.15 g m?3,在降雪初期或者降雪系统消散期,雪粒子含水量一般小于0.04 g m?3,能够很好地反映出整层降雪回波的雪粒子含水量。这些云雷达在降雪观测中的应用和初步分析结果可以更好的地了解降雪系统宏微观结构,为云模式的发展和人工影响天气中增雪潜力评估提供一些参考。 相似文献
20.
A prototype space-based cloud radar has been developed and was installed on an airplane to observe a precipitation system over Tianjin,China in July 2010.Ground-based S-band and Ka-band radars were used to examine the observational capability of the prototype.A cross-comparison algorithm between different wavelengths,spatial resolutions and platform radars is presented.The reflectivity biases,correlation coefficients and standard deviations between the radars are analyzed.The equivalent reflectivity bias between the S-and Ka-band radars were simulated with a given raindrop size distribution.The results indicated that reflectivity bias between the S-and Ka-band radars due to scattering properties was less than 5 dB,and for weak precipitation the bias was negligible.The prototype space-based cloud radar was able to measure a reasonable vertical profile of reflectivity,but the reflectivity below an altitude of 1.5 km above ground level was obscured by ground clutter.The measured reflectivity by the prototype space-based cloud radar was approximately 10.9 dB stronger than that by the S-band Doppler radar(SA radar),and 13.7 dB stronger than that by the ground-based cloud radar.The reflectivity measured by the SA radar was 0.4 dB stronger than that by the ground-based cloud radar.This study could provide a method for the quantitative examination of the observation ability for space-based radars. 相似文献