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1.
Aerosol particles can serve as cloud condensation nuclei(CCN)to influence orographic clouds.Autoconversion,which describes the initial formation of raindrops from the collision of cloud droplets,is an important process for aerosol-cloud-precipitation systems.In this study,seven autoconversion schemes are used to investigate the impact of CCN on orographic warm-phase clouds.As the initial cloud droplet concentration is increased from 100 cm-3to 1000 cm-3(to represent an increase in CCN),the cloud water increases and then the rainwater is suppressed due to a decrease in the autoconversion rate,leading to a spatial shift in surface precipitation.Intercomparison of the results from the autoconversion schemes show that the sensitivity of cloud water,rainwater,and surface precipitation to a change in the concentration of CCN is different from scheme to scheme.In particular,the decrease in orographic precipitation due to increasing CCN is found to range from-87%to-10%depending on the autoconversion scheme.Moreover,the surface precipitation distribution also changes significantly by scheme or CCN concentration,and the increase in the spillover(ratio of precipitation on the leeward side to total precipitation)induced by increased CCN ranges from 10%to 55%under different autoconversion schemes.The simulations suggest that autoconversion parameterization schemes should not be ignored in the interaction of aerosol and orographic cloud.  相似文献   

2.
利用中尺度WRF模式(V3.7),采用WDM6双参数微物理方案,对2014年7月26日12时—28日06时发生在华东地区的一次层状云降水天气进行数值模拟。通过改变模式中初始云凝结核(CCN)数浓度及参数化方案,进行敏感试验,对模拟结果进行对比分析。改变CCN数浓度的结果表明,CCN数浓度对降水的影响复杂、非线性,随着CCN数浓度的增大,降水量减小。云水、霰混合比始终增加,雨水混合比表现为先增加后减小再增加的趋势,冰晶混合比则与之相反,呈现先减小再增加再减小的趋势,雪晶混合比呈现先减小后增加的趋势;改变CCN参数化方案的结果表明,两者模拟降水落区有差别,三参数方案更接近实际;降水产生后,三参数方案的CCN浓度一直高于双参数方案,且数值变化不大;双参数方案的结果显示暖云降水加强,冷云降水略弱,三参数方案则显示暖云降水较弱,冷云降水较强。  相似文献   

3.
With the Reisner-2 bulk microphysical parameterization of the fifth-generation Pennsylvania State University–U.S. National Center for Atmospheric Research (PSU–NCAR) Mesoscale Model (MM5), this paper investigates the microphysical sensitivities of Typhoon Chanchu. Four different microphysical sensitivity experiments were designed with an objective to evaluate their respective impacts in modulating intensity forecasts and microphysics budgets of the typhoon. The set of sensitivity experiments were conducted ...  相似文献   

4.
Cloud-to-rain autoconversion process is an important player in aerosol loading, cloud morphology, and precipitation variations because it can modulate cloud microphysical characteristics depending on the participation of aerosols, and affects the spatio-temporal distribution and total amount of precipitation. By applying the Kessler, the Khairoutdinov-Kogan(KK), and the Dispersion autoconversion parameterization schemes in a set of sensitivity experiments, the indirect effects of aerosols on clouds and precipitation are investigated for a deep convective cloud system in Beijing under various aerosol concentration backgrounds from 50 to 10000 cm-3. Numerical experiments show that aerosol-induced precipitation change is strongly dependent on autoconversion parameterization schemes. For the Kessler scheme, the average cumulative precipitation is enhanced slightly with increasing aerosols, whereas surface precipitation is reduced significantly with increasing aerosols for the KK scheme. Moreover, precipitation varies non-monotonically for the Dispersion scheme, increasing with aerosols at lower concentrations and decreasing at higher concentrations.These different trends of aerosol-induced precipitation change are mainly ascribed to differences in rain water content under these three autoconversion parameterization schemes. Therefore, this study suggests that accurate parameterization of cloud microphysical processes, particularly the cloud-to-rain autoconversion process, is needed for improving the scientific understanding of aerosol-cloud-precipitation interactions.  相似文献   

5.
We investigate the effects of sea-salt aerosol(SSA) activated as cloud condensation nuclei on the microphysical processes, precipitation, and thermodynamics of a tropical cyclone(TC). The Weather Research and Forecasting model coupled with Chemistry(WRF-Chem) was used together with a parameterization of SSA production. Three simulations, with different levels of SSA emission(CTL, LOW, HIGH), were conducted. The simulation results show that SSA contributes to the processes of autoconversion of cloud water and accretion of cloud water by rain,thereby promoting rain formation. The latent heat release increases with SSA emission, slightly increasing horizontal wind speeds of the TC. The presence of SSA also regulates the thermodynamic structure and precipitation of the TC.In the HIGH simulation, higher latent heat release gives rise to stronger updrafts in the TC eyewall area, leading to enhanced precipitation. In the LOW simulation, due to decreased latent heat release, the temperature in the TC eye is lower, enhancing the downdrafts in the region; and because of conservation of mass, updrafts in the eyewall also strengthen slightly; as a result, precipitation in the LOW experiment is a little higher than that in the CTL experiment.Overall, the relationship between the precipitation rate and SSA emission is nonlinear.  相似文献   

6.
利用2006年"珍珠"台风影响福建省期间的酸雨监测资料和新一代天气雷达回波资料,对城市降水酸度分布特征及福州市短时段降水酸度进行分析,结果表明:来自海上的台风降水呈偏碱性;登陆后台风对福建省城市降水酸度的影响与其螺旋雨带上降水云团的移动路径及城市周边污染源分布有关;"珍珠"台风的短时段降水酸度并非保持恒定,对福州市降水酸度的影响会随着台风强度、风场结构的变化及螺旋雨带上降水云团途经下垫面城市大气污染排放状况而发生改变.  相似文献   

7.
Numerical simulations are carried out to investigate the effect of cloud condensation nuclei(CCN) concentrations on microphysical processes and precipitation characteristics of hailstorms. Two hailstorm cases are simulated, a spring case and a summer case, in a semiarid region of northern China, with the Regional Atmospheric Modeling System. The results are used to investigate the differences and similarities of the CCN effects between spring and summer hailstorms. The similarities are:(1) The total hydrometeor mixing ratio decreases, while the total ice-phase mixing ratio enhances, with increasing CCN concentration;(2) Enhancement of the CCN concentration results in the production of a greater amount of small-sized hydrometeor particles, but a lessening of large-sized hydrometeor particles;(3) As the CCN concentration increases, the supercooled cloud water and rainwater make a lesser contribution to hail, while the ice-phase hydrometeors take on active roles in the growth of hail;(4) When the CCN concentration increases, the amount of total precipitation lessens,while the role played by liquid-phase rainfall in the amount of total precipitation reduces, relatively, compared to that of icephase precipitation. The differences between the two storms include:(1) An increase in the CCN concentration tends to reduce pristine ice mixing ratios in the spring case but enhance them in the summer case;(2) Ice-phase hydrometeor particles contribute more to hail growth in the spring case, while liquid water contributes more in the summer case;(3) An increase in the CCN concentration has different effects on surface hail precipitation in different seasons.  相似文献   

8.
CCN concentration in the middle-lower troposphere over northern China was observed using a cloud condensation nucleus counter, MEE-130, installed on an IL-14 aircraft in the summer of 1983 and 1984. More than 60 sets of data (each flight as one set) were collected. The main results are: (1) in northern China, CCN concentration is 102-104/ cm3 near ground, decreases with increasing height and follows exponential distribution; (2) the local CCN concentration and its distribution with altitude are influenced by some meteorological factors: such as inversion, cloud and precipitation, wind and land—sea breeze etc. The inversion makes CCN significantly accumulate just below the inversion level; CCN concentration is lower inside clouds than outside clouds at same level; wind plays an important role of transporting CCN horizontally; (3) the CCN concentration is higher above the land than above the sea at same level; CCN concentration is one order of magnitude lower over the coastal cities like Qingdao than over the continental cities like Zhengzhou; (4) all these suggest that CCN in northern China comes mainly from continental surface layer. Densely—populated areas and industrial areas may produce more CCN.  相似文献   

9.
山西云微物理特征的地面观测   总被引:3,自引:1,他引:2  
利用连续气流纵向热梯度云凝结核仪和激光降水粒子谱测量仪对山西地面的云凝结核和雨滴谱进行了观测研究.研究结果表明,云凝结核(CCN)数浓度具有明显的日变化特征,1天出现了两次峰值,数浓度日变化与气象因子、人类活动有关.降水对CCN具有冲刷作用.利用关系式NCCN=CSk拟合得到的地面CCN活化谱参数C值明显较大,k值较高,属于典型的大陆型核谱.对层状云、层积云降水雨滴微物理特征参量分析发现:3次层状云、层积云降水雨滴数密度变化范围分别为74~229 m-3、305~743 m-3,平均含水量量级分别为10-2 g/m3、10-1g/m3,最大雨滴直径分别为1.78 mm、4.7 mm.对层状云降水雨滴的数密度和雨强贡献较大的分别是小于1 mm、0.2~2 mm的雨滴;对层积云降水雨滴的数密度和雨强贡献较大的分别是0.2~2 mm、1~3 mm的雨滴.层积云出现稳定谱的比例高于层状云.从瞬时谱型分布看,层状云出现单、双、三峰多,第四、五峰值的频率比较少,层积云雨滴谱分布没有出现指数型,常有多峰.从平均谱分布看,层状云谱宽窄于层积云,层状云雨滴平均谱服从指数分布,层积云曲线呈向下弯曲的趋势.对汾阳2008年7月17日一次积层混合云降水雨滴谱资料分析发现积层混合云降水雨滴微物理量起伏大,降水雨强主要由雨滴数密度决定.相同雨强下,若有相对更多的大雨滴,雷达反射率会更大一些.随着强回波云块的过境,雨滴数浓度、雨滴谱峰值个数、谱宽均明显增大.  相似文献   

10.
A two-dimensional cloud model with bin microphysics was used to investigate the effects of cloud condensation nuclei (CCN) concentrations and thermodynamic conditions on convective cloud and precipitation developments. Two different initial cloud droplet spectra were prescribed based on the total CCN concentrations of maritime (300 cm− 3) and continental (1000 cm− 3) air masses, and the model was run on eight thermodynamic conditions obtained from observational soundings. Six-hourly sounding data and 1-hourly precipitation data from two nearby weather stations in Korea were analyzed for the year 2002 to provide some observational support for the model results.For one small Convective Available Potential Energy (CAPE) ( 300 J kg− 1) sounding, the maritime and continental differences were incomparably large. The crucial difference was the production of ice phase hydrometeors in the maritime cloud and only water drops in the continental cloud. Ice phase hydrometeors and intrinsically large cloud drops of the maritime cloud eventually lead to significant precipitation. Meanwhile negligible precipitation developed from the continental cloud. For the three other small CAPE soundings, generally weak convective clouds developed but the maritime and continental clouds were of the same phases (both warm or both cold) and their differences were relatively small.Model runs with the four large CAPE ( 3000 J kg− 1) soundings demonstrated that the depth between the freezing level (FL) and the lifting condensation level (LCL) was crucial to determine whether a cloud becomes a cold cloud or not, which in turn was found to be a crucial factor to enhance cloud invigoration with the additional supply of freezing latent heat. For two large CAPE soundings, FL–LCL was so deep that penetration of FL was prohibitive, and precipitation was only mild in the maritime clouds and negligible in the continental clouds. Two other soundings of similarly large CAPE had small FL–LCL, and both the maritime and continental clouds became cold clouds. Precipitation was strong for both but much more so in the maritime clouds, while the maximum updraft velocity and the cloud top were slightly higher in continental clouds. Although limited to small CAPE cases, more precipitation for smaller FL–LCL for a selected group of precipitation and thermodynamic sounding data from Korea was in support of these model results in its tendency.These results clearly demonstrated that the CCN effects on cloud and precipitation developments critically depended on the given thermodynamic conditions and not just the CAPE but the entire structure of the thermodynamic profiles had to be taken into account.  相似文献   

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