一个简化的混合相云降水显式方案

该文提出一个新的混合相云降水显式方案,它预报2个云物理量,即云水（冷区为过冷云水）和降水（冷区为冰雪,暖区为雨）,考虑了7种云物理过程。文中给出了详细的方程组,可以作为一个子程序供大、中尺度天气模式使用。该方案还与详细微物理显式方案和暖云方案作了实例模拟比较。     

云滴数浓度影响混合型层状云降水的数值模拟

使用耦合了Morrison双参数微物理方案的中尺度WRF模式V2．2,对2008年1月25-29日发生在我国南方的冰雪天气过程进行了数值试验。在模式准确再现了此次天气过程形势演变特点的基础上,对模式微物理方案中云滴数浓度影响累积降水量的情况进行了敏感性试验,发现云滴数浓度对降水量的影响是复杂和非线性的。对此次天气过程中的微物理量进行了详细的分析,并从各种水成物粒子的发展演变上,讨论了云滴数浓度的增加在暖云和冷云两种降水机制上对降水产生的不同影响。结果表明,云滴数浓度越大,云水混合比就越大,云滴的尺度越小。雨滴对不同云滴数浓度的响应与云滴的情况相反,随着云滴数浓度的增加,雨滴数浓度减小,雨水也减少,暖云降水过程受到了抑制;冰晶和雪晶的数浓度的演变过程没有明显变化,而冰晶和雪晶的混合比是相应增加的,冷云降水过程得到了一定程度的增强。从本文模拟的个例来看,设置不同云滴数浓度所得到的总累计降水量的差异在1％以内。总的来说,增加云滴数浓度,降水量会减少。从比例上来看,增加云滴数浓度对暖云降水过程的抑制作用比对冷云降水过程的增强作用更为显著,但是在本文模拟的个例中,冷云降水过程占主导地位,减少的降水和增加的降水的绝对值在同一个量级上并且数值相近,它们相互抵消后得到的结果是降水量变化的绝对值大大减小了,这解释了增加云滴数浓度后模拟的总累积降水量变化不明显的原因。     

超强台风“威马逊”(2014)云微物理特征的模拟与对比分析

采用中尺度数值模式WRFv3.5对2014年超强台风“威马逊”进行数值模拟。利用雷达、卫星、自动站逐时降水资料,对比单参数WSM6云方案和双参数WDM6云方案在模拟台风路径、强度、降水分布及水成物含量上的差异,分析雨滴粒子的谱型特征及微物理源、汇项对云中雨水含量的影响。与上海台风研究所的最佳路径数据对比显示,两方案均较好地模拟出了台风“威马逊”的移动路径,WDM6方案的整体路径误差更小;模拟的强度差异则较为显著,WDM6方案的海平面最低气压值偏高,强度偏弱。两方案模拟的累积降雨分布虽与自动站实测资料基本一致,但WDM6方案模拟的强降水概率偏高,弱降水概率偏低。两方案模拟的对流区雪、霰、雨水含量均大于TRMM卫星反演结果,且WDM6方案的对流云较多,总体雨水含量偏高;两方案均模拟出了雷达回波分布的整体特征,但眼区尺度偏大,WDM6方案在融化层以下缺少眼墙之外的弱回波区且大于39 dBz的强回波区偏多,同样显示了雨水含量（或尺度）偏大。由于WDM6方案为暖雨（云、雨水）双参数模式,对云滴活化、云雨转换及云、雨谱型有一定的改进,其能较合理地模拟出雨滴谱随台风发展的演变特征;模拟显示,云、雨滴的收集碰并及固态粒子的融化是雨水的主要源项,WDM6方案增加了云雨水自动转化率及雨水碰并云水率,导致该方案的空中雨水含量偏高,且随高度的降低快速减小;此外,由于WDM6方案使用简单的寇拉公式进行云滴活化,初始云凝结核数的变化即可造成雪、霰、云雨水含量的改变,故建议在具体大气气溶胶条件下,对方案中的云滴生成参数化过程做相应的调整。     

A Simulation Study on the Characteristics of Cloud Microphysics of Heavy Rainfall in the Meiyu Front

A heavy rainfall in the Meiyu front during 4--5 July 2003 is simulated by use of the non-hydrostatic mesoscale model MM5 (V3--6) with different explicit cloud microphysical parameterization schemes. The characteristics of microphysical process of convective cloud are studied by the model outputs. The simulation study reveals that: (1) The mesoscale model MM5 with explicit cloud microphysical process is capable of simulating the instant heavy rainfall in the Meiyu front, the rainfall simulation could be improved significantly as the model resolution is increased, and the Goddard scheme is better than the Reisner or Schultz scheme. (2) The convective cloud in the Meiyu front has a comprehensive structure composed of solid, liquid and vapor phases of water, the mass density of water vapor is the largest one in the cloud; the next one is graupel, while those of ice, snow, rain water and the cloud water are almost same. The height at which mass density peaks for different hydrometeors is almost unchangeable during the heavy rainfall period. The mass density variation of rain water, ice, and graupel are consistent with that of ground precipitation, while that of water vapor in the low levels is 1--2 h earlier than the precipitation. (3) The main contribution to the water vapor budget in the atmosphere is the convergence of vapor flux through advection and convection, which provides the main vapor source of the rainfall. Besides the basic process of the auto-conversion of cloud water to rain water, there is an additional cloud microphysical process that is essential to the formation of instant heavy rainfall, the ice-phase crystals are transformed into graupels first and then the increased graupels mix with cloud water and accelerates the conversion of cloud water to rain water. The positive feedback mechanism between latent heat release and convection is the main cause to maintain and develop the heavy precipitation.     

Spatial patterns and trends of daily rainfall regime in Peninsular Malaysia during the southwest and northeast monsoons: 1975–2004

Model precipitation can be produced implicitly through convective parameterization schemes or explicitly through cloud microphysics schemes. These two precipitation production schemes control the spatial and temporal distribution of precipitation and consequently can yield distinct vertical profiles of heating and moistening in the atmosphere. The partition between implicit and explicit precipitation can be different as the model changes resolutions. Within the range of mesoscale resolutions (about 20 km) and cumulus scale, hybrid solutions are suggested, in which cumulus convection parameterization is acting together with the explicit form of representation. In this work, it is proposed that, as resolution increases, the convective scheme should convert less condensed water into precipitation. Part of the condensed water is made available to the cloud microphysics scheme and another part evaporates. At grid sizes smaller than 3 km, the convective scheme is still active in removing convective instability, but precipitation is produced by cloud microphysics. The Eta model version using KF cumulus parameterization was applied in this study. To evaluate the quantitative precipitation forecast, the Eta model with the KF scheme was used to simulate precipitation associated with the South Atlantic Convergence Zone (SACZ) and Cold Front (CF) events. Integrations with increasing horizontal resolutions were carried out for up to 5 days for the SACZ cases and up to 2 days for the CF cases. The precipitation partition showed that most of precipitation was generated by the implicit scheme. As the grid size decreased, the implicit precipitation increased and the explicit decreased. However, as model horizontal resolution increases, it is expected that precipitation be represented more explicitly. In the KF scheme, the fraction of liquid water or ice, generated by the scheme, which is converted into rain or snow is controlled by a parameter S ₁. An additional parameter was introduced into KF scheme and the parameter acts to evaporate a fraction of liquid water or ice left in the model grid by S ₁ and return moisture to the resolved scale. An F parameter was introduced to combine the effects of S ₁ and S ₂ parameters. The F parameter gives a measure of the conversion of cloud liquid water or ice to convective precipitation. A function dependent on the horizontal resolution was introduced into the KF scheme to influence the implicit and explicit precipitation partition. The explicit precipitation increased with model resolution. This function reduced the positive precipitation bias at all thresholds and for the studied weather systems. With increased horizontal resolution, the maximum precipitation area was better positioned and the total precipitation became closer to observations. Skill scores for all events at different forecast ranges showed precipitation forecast improvement with the inclusion of the function F.     

不同云方案对祁连山降水模拟的影响

应用MM5中尺度模式,选用4种不同云微物理方案(Dudhia简单冰相方案、Reisner混合相方案、Reisner2霰方案和Schultz微物理方案),对2002年7月12-13日祁连山区降水过程进行了数值模拟试验。模拟结果的对比分析表明,不同云微物理方案在祁连山区降水的模拟中对降水落区的模拟均偏南;除Reisner2霰方案外,其他3种方案对降水中心落点的模拟影响不大,降水中心强度对云微物理方案不敏感;显式降水和参数化降水对云微物理方案有不同程度的依赖性;云微物理过程通过影响动力条件发生发展的时间和强度,来影响强降水发生的时间和强度。通过各云微物理参数的分析发现,各物理过程中微物理参数参与降水的过程不同:对Dudhia简单冰相方案来说,雨水和云水是形成降水的主要过程;Reisner混合相方案中降水的形成主要是由于雨水、云水、雪和霰的碰并过程,冰晶的碰并相对较弱;在Reisner2霰方案中,雨水、云水、冰晶、雪和霰均参与碰并碰冻过程;Schultz微物理方案中冰晶、雪和霰的碰并过程更为重要。     

祁连山夏季地形云结构和云微物理过程的模拟研究(I):模式云物理方案和地形云结构

对三维非静力中尺度模式ARPS的云降水微物理方案进行了改进,利用改进后的ARPS模式模拟了祁连山地区夏季的两个地形云个例,通过对各自模拟结果的对比分析并结合实况资料研究了夏季祁连山地区地形云的发展状况、动力场特征、降水特征以及云微物理结构特征。研究结果表明,地形云的发展受地形影响很大,地形的抬升促进了云和降水的发展,地形的作用也改变了地面降水特征,使云的宏、微观物理结构发生较大变化。     

一次梅雨锋暴雨云物理特征的数值模拟研究

利用中尺度数值模式MM5(V3.6),选用模式中不同的显式云物理方案,对2003年7月4-5日发生在江淮流域的梅雨锋暴雨过程进行了数值模拟,并根据模拟结果对造成此次暴雨过程的对流云团的微物理特征进行了分析.研究结果表明:(1) 具有详细云物理过程的中尺度模式MM5对短时强降水过程具有较好的模拟能力,提高MM5模式的分辨率,可以更好地模拟短时梅雨锋暴雨过程,模式中的Goddard云物理方案的模拟结果要优于Reisner方案和Schultz方案.(2) 梅雨锋对流云团是一种复杂的固、液、气三相混合体结构,在云体区域内的平均质量密度分布中,水汽的质量密度最大,其次是霰,而冰晶、雪、云水和雨水的质量密度较小且数值大小彼此接近,各种相态粒子质量密度峰值出现的高度随时间无明显变化.雨水、云冰和霰的质量密度随时间演变规律与地面降水强度的变化特征相一致,近地面层水汽密度随时间的演变规律比地面降水强度提前1-2个小时,水汽通量的辐合对暴雨时段内水汽的补充和维持起到了重要的作用.(3) 除了最基本的云水向雨水转化的云微物理过程之外,此次降水过程还显示,在中层500-700 hPa范围内雪、冰晶等冰相粒子首先转化为霰粒子,而霰和云水的结合进一步加速(剧)云水向雨水的转换,成为短时特大暴雨形成不可或缺的动力机制,云物理过程中的相变潜热与对流运动的正反馈机制是促进暴雨维持和发展的最重要热力因子.     

A Two-Moment Bulk Microphysics Coupled with a Mesoscale Model WRF: Model Description and First Results

The Chinese Academy of Meteorological Sciences (CAMS) two-moment bulk microphysics scheme was adopted in this study to investigate the representation of cloud and precipitation processes under different environmental conditions.The scheme predicts the mixing ratio of water vapor as well as the mixing ratios and number concentrations of cloud droplets,rain,ice,snow,and graupel.A new parameterization approach to simulate heterogeneous droplet activation was developed in this scheme.Furthermore,the improved CAMS scheme was coupled with the Weather Research and Forecasting model (WRF v3.1),which made it possible to simulate the microphysics of clouds and precipitation as well as the cloud-aerosol interactions in selected atmospheric condition.The rain event occurring on 27-28 December 2008 in eastern China was simulated using the CAMS scheme and three sophisticated microphysics schemes in the WRF model.Results showed that the simulated 36-h accumulated precipitations were generally agreed with observation data,and the CAMS scheme performed well in the southern area of the nested domain.The radar reflectivity,the averaged precipitation intensity,and the hydrometeor mixing ratios simulated by the CAMS scheme were generally consistent with those from other microphysics schemes.The hydrometeor number concentrations simulated by the CAMS scheme were also close to the experiential values in stratus clouds.The model results suggest that the CAMS scheme performs reasonably well in describing the microphysics of clouds and precipitation in the mesoscale WRF model.     

A numerical investigation of a moderate coastal storm with intense precipitation

Abstract

In this study, the development of a moderate coastal storm with intense precipitation that occurred during 12–14 February 1993 is examined using a high‐resolution version of the Canadian Regional Finite‐element (RFE) model with more realistic physical representations. It is shown that the improved RFE model predicts well the coastal cyclogenesis events and also the distribution and intensity of heavy mixed precipitation (rain and snow) associated with the storm. It is found that the cyclogenesis takes place in response to the low‐level inshore advection of high‐θ_e air from the maritime boundary layer, and the approach of a mid‐level shortwave trough with a warm pool above that is previously associated with a decaying cyclone upstream. More rapid deepening of the cyclone ensues as intense precipitation falls along the warm and cold fronts near the cyclone centre.

Diagnosis of the control and sensitivity simulations reveals that the low‐level inshore warm advection and the propagation of the stratospheric warm pool contribute more significantly to the surface pressure falls during the incipient stage, whereas the mid‐level shortwave trough plays an important role in the cyclogenesis at later stages. Overall, latent heat release accounts for about 50% of the cyclone's total deepening, in agreement with the presence of a moderate baroclinic environment and the generation of intense precipitation.

The diabatic and kinematic structures near the rain‐snow boundary are examined to gain insight into the influence of melting snow on the cyclogenesis. It is shown that the improved RFE model reproduces well the rain‐snow boundary structures as previously observed. Moreover, a thermally indirect circulation (perturbation) can be seen in the vicinity of the rain‐snow boundary. It is found, however, that melting of snow tends to produce a weak negative or negligible impact on the cyclogenesis, as opposed to previous hypotheses.     

积层混合云结构和云微物理的数值模拟

对三维非静力中尺度模式ARPS的云微物理方案进行了改进,利用改进后的模式模拟了华北地区的积层混合云降水个例,通过对模拟结果的分析并结合实况资料研究了积层混合云的降水特征、云物理结构特征和微物理过程。结果表明,积层混合云降水分布不均匀,雨区中存在多个强降水中心,云系中微物理量在水平和垂直方向上分布都不均匀,积云中的垂直液态水积分含量大大高于层云中含量,此次降水冰相过程占主导地位,霰的融化是最主要的雨生成项。     

云微物理参数化对华北降雪影响的数值模拟

对发生在华北地区的一次降雪过程进行了中尺度数值模拟。结果表明,高纬强冷空气南下和低纬倒槽的水汽输送是造成这次长时间降雪过程的主要原因。采用混合方案的中尺度数值模拟表明,这次降雪天气不是对流云造成的,而是稳定性的非对流云降雪。敏感性试验也表明,采用其他积云参数化方案对模拟的降雪量基本没有影响。控制试验模拟的24h降雪量与实际观测比较吻合。模拟结果表明,当采用Dudhia简单冰相方案时,会有过多的云冰、过冷却水及雪;当采用Reisner 1混合相方案时,会有过多的云冰和雪;修改的各个Reisner 2方案对此次降雪的预报改进不大,但各个Reisner 2方案的敏感性试验中云冰混合比、过冷却水混合比和雪混合比稍微有差异。     

A Simulating Study on Resolvable-Scale Microphysical Parameterization in a Mesoscale Model

The Penn State/ NCAR Mesoscale Model (MM5) is used to simulate the precipitation event that oc-curred during 1-2 May 1994 to the south of the Yangtze River. In five experiments the Kain-Fritsch scheme is made use of for the subgrid-scale convective precipitation, but five different resolvable-scale microphysical parameterization schemes are employed. They are the simple super-saturation removal scheme, the warm rain scheme of Hsie et al. (1984), the simple ice scheme of Dudhia (1989), the complex mixed-phase scheme developed by Reisner et al. (1993). and the GSFC microphysical scheme with graupel. Our interest is how the various resolvable-scale schemes affect the domain-averaged precipitation, the pre-cipitation distribution, the sea level pressure, the cloud water and the cloud ice.Through a series of experiments about a warm sector rainfall case, results show that although the dif-ferent resolvable-scale scheme is used, the differences of the precipitation characteristics among all five runs are not very obvious. However, the precipitation is over-predicted and the strong mesoscale low is produced by the simple super-saturation removal scheme. The warm rain scheme with the inclusion of condensation and evaporation under-predicts the precipitation and allows the cloud water to reach the 300 hPa level The scheme of the addition of graupel increases the resolvable-scale precipitation by about 20%–30%. The inclusion of supercooled liquid water in the grid-scale scheme does not affect significantly the results.     

WRF模式云参数化方案对一次深对流系统模拟的验证和改进

使用中尺度数值模式WRF中的双参数云微物理方案WDM6针对2008年台风“凤凰”登陆过程中造成的强降水进行数值模拟,通过卫星模拟器利用MTSAT-1R和TRMM卫星观测的红外云顶黑体亮温TBB、PR雷达反射率资料使用统计方法验证模拟结果。通过修改云水向雨水自动转化过程、冰晶核化过程、雪和霰的下落末速度、雪和霰的截距进行敏感性试验,减小模拟结果和卫星观测结果的差异。研究结果表明:WDM6方案模拟的台风“凤凰”登陆后的降水,强对流云系及对流柱状雷达回波基本符合实况,但模拟结果局部偏强。WDM6方案模拟产生了较多的浅对流云,低估了对流云系的出现频率。不同云类型模拟的雷达回波均偏强,对流云系雷达回波垂直分布接近观测。敏感性试验结果说明修改WDM6方案中云水向雨水自动转化率有效地改善了模拟效果。同时发现云滴初始数浓度影响云水向雨水自动转化率并最终影响云系结构和雷达反射率的模拟结果,过高的云滴初始数浓度会使模拟结果变差。     

北京层状云人工增雨数值模拟试验和机理研究

在中尺度WRF 模式的Morrison 双参数方案中引入了AgI 粒子与云相互作用的过程,在WRF 模式中实现了催化功能。利用加入了催化方案的中尺度模式对2008 年3 月20～21 日环北京地区一次层状云系降水过程进行模拟和催化试验。模拟自然降水与实测结果一致,分析微物理特征并在所得分析基础上进行催化试验。研究在不同催化剂量、高度和时刻进行试验对降水的影响。结果表明:以20 g 的碘化银进行催化作业,在催化后的前30min 之内,地面雨量轻微减小,最大累积减雨量为2010 t,30 min 后,净增雨量迅速增加,最大累积增雨量达到了3.4×105 t。催化开始阶段的减雨主要是由于播撒AgI 后,云水减少而雪晶增多,导致雨滴碰并云滴,云滴向雨滴自动转化过程的减少以及雪晶碰并雨滴过程的增多,然而空中增多的雪晶尚未下落到暖区融化成雨滴。而第二阶段的增雨则是空中增多的雪晶逐渐下落到暖区,雪晶融化成雨滴过程增多。AgI 的播撒率对降水量有明显影响,过量催化会使雪晶平均质量减少,下落速度锐减,从而雪融化成雨水减少,导致雨量减弱,不同催化高度和催化时间的催化结果表明在过冷水含量比较丰富而冰雪晶含量偏少的区域进行催化,增雨效果显著。     

一次江淮气旋及其中尺度系统的数值模拟

本文在十一层原始方程模式中引入Fritsch-Chappell一维云模式，对1982年5月12日江淮气旋上中尺度系统进行了模拟试验，分析表明:Fritsch-Chappell一维云模式对深厚积云的考虑细致合理，比郭晓岚积云参数化方案优越，它能模拟出中尺度系统的一些特征。通过数值计算发现:中尺度江淮气旋是对流层低层的天气系统，气压场上具有中尺度低压的某些特征；对流天气的出现，使得中尺度江淮气旋得到发展，但这种发展有一个变化过程，在对流发展加强时，对流引起的动量变化以及下沉气流造成的低层冷却作用，使其有一个暂时的减弱过程，当对流运动趋于减弱时，气旋才得以发展。     

高分辨率GRAPES模式中云微物理方案对强降水的模拟和诊断研究

利用高分辨率GRAPES—Meso中双参数云微物理方案,对我国两次强降水过程进行数值模拟,并与模式中WSM6和NCEP5方案进行对比分析,结合多种观测资料,诊断评估方案的预报性能.同时研究伴随强对流性降水中的关键云物理过程。个例研究表明,对流发展旺盛的云团中,冰相粒子尤其是霰粒子对对流的发展与降水起着主导作用,霰的融化是强降水的主要来源,而周围的层状云区域霰粒子的分布极少,主要受雪的融化与暖云降水的影n向。双参数方案模拟的雨带走向、范围和降水强度与实况拟合较好,同时在对流单体的最大回波高度与强度、冰晶的分布与云砧结构等方面也具有一定优势,但冰晶含量和回波顶高度略低于观测,这都为双参数方案的优化与业务应用提供重要的支持。     

梅雨锋暴雨中云物理过程的观测和数值模拟

Cloud micro-physical structures in a precipitation system associated with the Meiyu front are observedusing the balloon-borne Precipitation Particle Image Sensor at Baoshan observatory station, Shanghaiduring June and July 1999. The vertical distributions of various cloud particle size, number density, andmass density are retrieved from the observations. Analyses of observations show that ice-phase particles(ice crystals, graupel, snowflakes, and frozen drops) often exist in the cloud of torrential rain associatedwith the Meiyu front. Among the various particles, ice crystals and graupel are the most numerous, butgraupel and snow have the highest mass density. Ice-phase particles coexist with liquid water dropletsnear the 0℃ level. The graupel is similarly distributed with height as the ice crystals. Raindrops belowthe 0℃ level are mainly from melted grauple, snowflakes and frozen drops. They may further grow largerby coalescence with smaller ones as they fall from the cloud base. Numerical simulations using the non-hydrostatic meso-scale model MM5 with the Reisner graupel explicit moisture scheme confirm the mainobservational results. Rain water at the lower level is mainly generated from the melting of snow andgraupel falling from the upper level where snow and graupel are generated and grown from collection withcloud and rain water. Thus the mixed-phase cloud process, in which ice phase coexists and interacts withliquid phase (cloud and rain drops), plays the most important role in the formation and development ofheavy convective rainfall in the Meiyu frontal system.     

On the sensitivity of predictions of maritime cyclogenesis to convective precipitation and sea temperature

Abstract

The influences of surface fluxes and convective precipitation are investigated for two 36‐h periods of cyclogenesis over the northeastern Pacific Ocean. Three methods are tested of specifying the fraction of moisture supply that produces convective precipitation in a modified form of Kuo's (1974) parametrization scheme using an 8‐level primitive equations model.

When convection is included, precipitation amounts are greater and the cyclone deepening is better predicted than when convection is not included. Predicted cyclogenesis is very sensitive to sea temperature. As the low moves over warmer water, the effect of sensible heating is to increase the moisture convergence in the atmospheric boundary layer. This increases the precipitation rates and accelerates deepening. It is concluded that the CISK mechanism plays an important role in extratropical cyclogenesis.