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1.
This paper describes explicit and parameterized simulations of midsummer precipitation over the continental United States for two distinct episodes: moderate large-scale forcing and weak forcing. The objective is to demonstrate the capability of explicit convection at currently affordable grid-resolution and compare it with parameterized realizations. Under moderate forcing, 3-kin grid-resolution explicit simulations represent rainfall coherence remarkably well. The observed daily convective generation near the Continental Divide and the subsequent organization and propagation are reproduced qualitatively. The propagation speed, zonal extent and duration of the rainfall streaks compare favorably with their observed counterparts, although the streak frequency is underestimated. The simulations at -10-km grid-resolution applying conventional convective parameterization schemes also replicate reasonably well the diurnal convective regeneration in moderate forcing. The performance of the 3-km grid-resolution model demonstrates the potential of -1-km-resolution explicit cloud-resolving models for the prediction of warm season precipitation for moderately forced environments. In weak forcing conditions, however, predictions of precipitation coherence and diurnal variability are much poorer. This suggests that an even finer resolution explicit model is required to adequately treat convective initiation and upscale organization typical of the warm season over the continental U.S. 相似文献
2.
N. E. Veremei Yu. A. Dovgalyuk S. V. Efimov A. M. Nosova A. A. Pechenkin 《Russian Meteorology and Hydrology》2013,38(1):20-27
The computation of thunderstorm and shower activity on the territory of Russia during the warm period (June–August) of 1981–2000 for four observation times (00:00, 06:00, 12:00, and 18:00) is carried out using the local convective cloud model (CCM) and the ERA-40 reanalysis data on the vertical distribution of temperature and humidity. The spatial grid with the resolution of 2.5 × 2.5° is used for the computation. Collected and analyzed are the long-term (1936–1965) in situ data on the distribution of the number of days with the thunderstorm on the territory of Russia using the observational data from the ground-based meteorological stations (about 600 stations located in different regions). As a result, the distribution of the number of days with the thunderstorm and with the convective precipitation on the territory of Russia is plotted and analyzed. It agrees on the whole with the observed data. It is demonstrated that the number of days with the thunderstorm and with the convective precipitation correlate well with each other, that also corresponds to the observational data. It is shown that CCM is applicable to the simulation of cloud convection and associated phenomena. 相似文献
3.
Regional climate model projections for the State of Washington 总被引:3,自引:1,他引:2
Global climate models do not have sufficient spatial resolution to represent the atmospheric and land surface processes that determine the unique regional climate of the State of Washington. Regional climate models explicitly simulate the interactions between the large-scale weather patterns simulated by a global model and the local terrain. We have performed two 100-year regional climate simulations using the Weather Research and Forecasting (WRF) model developed at the National Center for Atmospheric Research (NCAR). One simulation is forced by the NCAR Community Climate System Model version 3 (CCSM3) and the second is forced by a simulation of the Max Plank Institute, Hamburg, global model (ECHAM5). The mesoscale simulations produce regional changes in snow cover, cloudiness, and circulation patterns associated with interactions between the large-scale climate change and the regional topography and land-water contrasts. These changes substantially alter the temperature and precipitation trends over the region relative to the global model result or statistical downscaling. To illustrate this effect, we analyze the changes from the current climate (1970–1999) to the mid twenty-first century (2030–2059). Changes in seasonal-mean temperature, precipitation, and snowpack are presented. Several climatological indices of extreme daily weather are also presented: precipitation intensity, fraction of precipitation occurring in extreme daily events, heat wave frequency, growing season length, and frequency of warm nights. Despite somewhat different changes in seasonal precipitation and temperature from the two regional simulations, consistent results for changes in snowpack and extreme precipitation are found in both simulations. 相似文献
4.
Steven C. Chan Elizabeth J. Kendon Hayley J. Fowler Stephen Blenkinsop Christopher A. T. Ferro David B. Stephenson 《Climate Dynamics》2013,41(5-6):1475-1495
Three different resolution (50, 12, and 1.5 km) regional climate model simulations are compared in terms of their ability to simulate moderate and high daily precipitation events over the southern United Kingdom. The convection-permitting 1.5-km simulation is carried out without convective parametrisation. As in previous studies, increasing resolution (especially from 50 to 12 km) is found to improve the representation of orographic precipitation. The 50-km simulation underestimates mean precipitation over the mountainous region of Wales, and event intensity tends to be too weak; this bias is reduced in both the 12- and 1.5-km simulations for both summer and winter. In south–east England lowlands where summer extremes are mostly convective, increasing resolution does not necessary lead to an improvement in the simulation. For the 12-km simulation, simulated daily extreme events are overly intense. Even though the average intensity of summer daily extremes is improved in the 1.5-km simulation, this simulation has a poorer mean bias with too many events exceeding high thresholds. Spatial density and clustering of summer extremes in south–east England are poorly simulated in both the 12- and 1.5-km simulations. In general, we have not found any clear evidence to show that the 1.5-km simulation is superior to the 12-km simulation, or vice versa at the daily level. 相似文献
5.
Frédéric Hourdin Jean-Yves Grandpeix Catherine Rio Sandrine Bony Arnaud Jam Frédérique Cheruy Nicolas Rochetin Laurent Fairhead Abderrahmane Idelkadi Ionela Musat Jean-Louis Dufresne Alain Lahellec Marie-Pierre Lefebvre Romain Roehrig 《Climate Dynamics》2013,40(9-10):2193-2222
Based on a decade of research on cloud processes, a new version of the LMDZ atmospheric general circulation model has been developed that corresponds to a complete recasting of the parameterization of turbulence, convection and clouds. This LMDZ5B version includes a mass-flux representation of the thermal plumes or rolls of the convective boundary layer, coupled to a bi-Gaussian statistical cloud scheme, as well as a parameterization of the cold pools generated below cumulonimbus by re-evaporation of convective precipitation. The triggering and closure of deep convection are now controlled by lifting processes in the sub-cloud layer. An available lifting energy and lifting power are provided both by the thermal plumes and by the spread of cold pools. The individual parameterizations were carefully validated against the results of explicit high resolution simulations. Here we present the work done to go from those new concepts and developments to a full 3D atmospheric model, used in particular for climate change projections with the IPSL-CM5B coupled model. Based on a series of sensitivity experiments, we document the differences with the previous LMDZ5A version distinguishing the role of parameterization changes from that of model tuning. Improvements found previously in single-column simulations of case studies are confirmed in the 3D model: (1) the convective boundary layer and cumulus clouds are better represented and (2) the diurnal cycle of convective rainfall over continents is delayed by several hours, solving a longstanding problem in climate modeling. The variability of tropical rainfall is also larger in LMDZ5B at intraseasonal time-scales. Significant biases of the LMDZ5A model however remain, or are even sometimes amplified. The paper emphasizes the importance of parameterization improvements and model tuning in the frame of climate change studies as well as the new paradigm that represents the improvement of 3D climate models under the control of single-column case studies simulations. 相似文献
6.
This study used the Global/Regional Assimilation and PrEdiction System Single-Column Model(GRAPES_SCM)to simulate monsoon precipitation with deep convective cloud and associated cirrus during the Tropical Warm Pool International Cloud Experiment(TWP-ICE), especially during the active and suppressed monsoon periods. Four cases with different heterogeneous nucleation parameterizations were simulated by using the ensemble method. All simulations clearly separated the active and suppressed monsoon periods, and they reproduced the major characteristics of monsoonal cloud such as the total cloud hydrometeor mixing ratio distribution,and precipitation and radiation properties. The results showed that the number concentration production rate of different heterogeneous nucleation parameterizations varied substantially under the given temperature and water vapor mixing ratio. However, ice formation and precipitation during the monsoon period were affected only slightly by the different heterogeneous nucleation parameterizations. This study also captured clear competition between different ice formation processes. 相似文献
7.
The fifth-generation Pennsylvania State University/NCAR Mesoscale Model Version 3 (MM5V3) was used to simulate extreme heavy rainfall events over the Yangtze River Basin in June 1999. The effects of model's horizontal and vertical resolution on the extreme climate events were investigated in detail. In principle, the model was able to characterize the spatial distribution of monthly heavy precipitation. The results indicated that the increase in horizontal resolution could reduce the bias of the modeled heavy rain and reasonably simulate the change of daily precipitation during the study period. A finer vertical resolution led to obviously improve rainfall simulations with smaller biases, and hence, better resolve heavy rainfall events. The increase in both horizontal and vertical resolution could produce better predictions of heavy rainfall events. Not only the rainfall simulation altered in the cases of different horizontal and vertical grid spacing, but also other meteorological fields demonstrated diverse variations in terms of resolution change in the model. An evident improvement in the simulated sea level pressure resulted from the increase of horizontal resolution, but the simulation was insensitive to vertical grid spacing. The increase in vertical resolution could enhance the simulation of surface temperature as well as atmospheric circulation at low levels, while the simulation of circulation at middle and upper levels were found to be much less dependent on changing resolution. In addition, cumulus parameterization schemes showed high sensitivity to horizontal resolution. Different convective schemes exhibited large discrepancies in rainfall simulations with regards to changing resolution. The percentage of convective precipitation in the Grell scheme increased with increasing horizontal resolution. In contrast, the Kain-Fritsch scheme caused a reduced ratio of convective precipitation to total rainfall accumulations corresponding to increasing horizontal resolution. 相似文献
8.
高分辨率模式中积云参数化方案对模拟台风“凡亚比”的影响 总被引:1,自引:0,他引:1
在高水平分辨率模式(3~6 km)中,对于是否应该再使用积云参数化方案,仍存在着争论.为此,利用WRF模式,在5 km水平分辨率下,研究了不同云降水方案对一次台风过程模拟的影响,并对影响原因进行了初步探索.结果表明,即使在5 km高水平分辨率下,使用积云参数化方案仍能有效改善对台风路径的模拟,同时,成熟的混合冰相微物理方案对模拟台风路径也非常重要;对台风强度模拟,对积云参数化方案的选择较为敏感和复杂;在48 h预报时效内,只使用微物理方案模拟的降水较好,使用积云参数化方案容易产生较多的虚假降水,但能改善第3天24 h累积降水模拟.这些研究结果为利用高水平分辨率模式模拟台风和改进积云参数化方案提供一定借鉴. 相似文献
9.
Simulating the diurnal cycle of rainfall in global climate models: resolution versus parameterization 总被引:1,自引:1,他引:0
Paul A. Dirmeyer Benjamin A. Cash James L. Kinter III Thomas Jung Lawrence Marx Masaki Satoh Cristiana Stan Hirofumi Tomita Peter Towers Nils Wedi Deepthi Achuthavarier Jennifer M. Adams Eric L. Altshuler Bohua Huang Emilia K. Jin Julia Manganello 《Climate Dynamics》2012,39(1-2):399-418
The effects of horizontal resolution and the treatment of convection on simulation of the diurnal cycle of precipitation during boreal summer are analyzed in several innovative weather and climate model integrations. The simulations include: season-long integrations of the Non-hydrostatic Icosahedral Atmospheric Model (NICAM) with explicit clouds and convection; year-long integrations of the operational Integrated Forecast System (IFS) from the European Centre for Medium-range Weather Forecasts at three resolutions (125, 39 and 16 km); seasonal simulations of the same model at 10 km resolution; and seasonal simulations of the National Center for Atmospheric Research (NCAR) low-resolution climate model with and without an embedded two-dimensional cloud-resolving model in each grid box. NICAM with explicit convection simulates best the phase of the diurnal cycle, as well as many regional features such as rainfall triggered by advancing sea breezes or high topography. However, NICAM greatly overestimates mean rainfall and the magnitude of the diurnal cycle. Introduction of an embedded cloud model within the NCAR model significantly improves global statistics of the seasonal mean and diurnal cycle of rainfall, as well as many regional features. However, errors often remain larger than for the other higher-resolution models. Increasing resolution alone has little impact on the timing of daily rainfall in IFS with parameterized convection, yet the amplitude of the diurnal cycle does improve along with the representation of mean rainfall. Variations during the day in atmospheric prognostic fields appear quite similar among models, suggesting that the distinctive treatments of model physics account for the differences in representing the diurnal cycle of precipitation. 相似文献
10.
This study evaluates the sensitivity of ecosystem models to changes in the horizontal resolution of version 2 of the National
Centre for Atmospheric Research Community Climate Model (CCM2). A previous study has shown that the distributions of natural
ecosystems predicted by vegetation models using coarse resolution present-day climate simulations are poorly simulated. It
is usually assumed that increasing the spatial resolution of general circulation models (GCMs) will improve the simulation
of climate, and hence will increase our level of confidence in the use of GCM output for impacts studies. The principal goals
of this study is to investigate this hypothesis and to identify which biomes are more affected by the changes in spatial resolution
of the forcing climate. The ecosystem models used are the BIOME-1 model and a version of the Holdridge scheme. The climate
simulations come from a set of experiments in which CCM2 was run with increasing horizontal resolutions. The biome distributions
predicted using CCM2 climates are compared against biome distributions predicted using observed climate datasets. Results
show that increasing the resolution of CCM2 produces a significant improvement of the global-scale vegetation prediction,
indicating that a higher level of confidence can be vested in the global-scale prediction of natural ecosystems using medium
and high resolution GCMs. However, not all biomes are equally affected by the increased spatial resolution, and although certain
biome distributions are improved (e.g. hot desert, tropical seasonal forest), others remain globally poorly predicted even
at high resolution (e.g. grasses and xerophytic woods). In addition, these results show that some climatic biases are enhanced
with increasing resolution (e.g. in mountain ranges), resulting in the inadequate prediction of biomes.
Received: 4 March 1997 / Accepted: 10 December 1997 相似文献
11.
Precipitation and associated cloud hydrometeors have large temporal and
spatial variability, which makes accurate quantitative precipitation
forecasting difficult. Thus, dependence of accurate precipitation and
associated cloud simulation on temporal and spatial scales becomes an
important issue. We report a cloud-resolving modeling analysis on this issue
by comparing the control experiment with experiments perturbed by initial
temperature, water vapor, and cloud conditions. The simulation is considered
to be accurate only if the root-mean-squared difference between the
perturbation experiments and the control experiment is smaller than the
standard deviation. The analysis may suggest that accurate precipitation and
cloud simulations cannot be obtained on both fine temporal and spatial
scales simultaneously, which limits quantitative precipitation forecasting.
The accurate simulation of water vapor convergence could lead to accurate
precipitation and cloud simulations on daily time scales, but it may not be
beneficial to precipitation and cloud simulations on hourly time scales due
to the dominance of cloud processes. 相似文献
12.
中国东部云-降水对应关系的分析与模式评估 总被引:2,自引:1,他引:1
为评估和改进模式中不同类型云与降水的对应关系,利用1998—2007年卫星-台站融合降水资料和国际卫星云气候计划的卫星观测云资料,采用诊断方法分析了中国东部季风区冬季层云、夏季对流云、层云与降水的水平分布及季节变化对应关系,并评估了BCC_AGCM模式的T42和T106分辨率版本对云-降水对应关系的模拟能力。观测资料分析结果表明,中国东部冬季云带和雨带都稳定少动,降水主要来自雨层云和高层云,南部沿海层云和层积云也对降水有贡献;夏季,中国东部表现为层积混合云降水特征,对流云带与降水带具有较好的对应关系,并具有一致的移动特征。对流降水主要来自深对流云和卷层云,深对流云云量和降水中心完全吻合,卷层云云带则表现出比深对流云主体和降水带偏北的现象;层云降水主要来自高层云和层积云。模式评估结果表明,中、低分辨率版本的BCC_AGCM模式均模拟出了冬季层云和稳定少动的降水带、夏季深对流云、卷层云和降水带的对应关系及随季风推进的移动特征。与T42模式版本相比,T106模式版本在夏季对流云云量的模拟及其与降水带的对应关系方面有所改善,说明改进的BCC_AGCM积云对流参数化方案与高分辨率模式网格更匹配,但冬季层云云量模拟误差变大,与降水带的对应关系变差,其原因值得进一步分析研究。 相似文献
13.
本文利用中国科学院大气物理研究所地球系统模式CAS-ESM和NCAR CESM中的气候系统模式开展了一系列不同物理参数化方案和水平分辨率的模拟试验,并针对欧亚大陆逐日降水特征模拟性能进行分析研究。本研究进行了四组时长为19年(1998~2016年)的AMIP(Atmospheric Model Intercomparison Project)数值积分试验:在1.9°×2.5°的低分辨率下NCAR CESM模式使用CAM5物理参数化方案组合(记为CESM),在1.4°×1.4°的低水平分辨率下CAS-ESM模式使用CAM4与CAM5两种不同物理参数化方案组合(依次记为Lcam4和Lcam5),在0.5°×0.5°的高水平分辨率下CAS-ESM模式使用CAM5物理参数化方案(记为Hcam5)。通过与GPCC(Global Precipitation Climatology Centre)、CMORPH(CPC MORPHing technique)观测资料比较,两个模式较好地再现了平均降水特征和极端降水的气候态,但模式的降水频率偏大、降水强度偏弱。CESM的大雨日数与观测较为接近,Hcam5模拟的日最大降水量与观测最接近。针对CAS-ESM模式,不同物理参数化方案和水平分辨率均对降水特征产生影响,其中提高分辨率对降水特征的模拟有显著的改进。Lcam4和Lcam5相比,Hcam5显著提高了极端降水的模拟性能。在欧亚大陆中高纬地区,Lcam4的降水频率高于Lcam5;而在中国东部,Hcam5的降水频率比Lcam5小,与GPCC偏差更小。进一步分析的结果表明,与Lcam5相比,在欧洲地区Lcam4中的大尺度降水较多,水汽输送更强。在中国东部,Hcam5中对流性降水频率比Lcam5更小,而大尺度降水和水汽输送更大,使得高分辨率的模拟试验性能提高。 相似文献
14.
On the role of resolution and topography in the simulation of East Asia precipitation 总被引:13,自引:0,他引:13
Xuejie Gao Ying Xu Zongci Zhao J. S. Pal F. Giorgi 《Theoretical and Applied Climatology》2006,86(1-4):173-185
Summary In this paper, we investigate the role that horizontal resolution plays in the simulation of East Asia precipitation. Two
sets of numerical experiments are performed using the Regional Climate Model (RegCM2) nested in one-way mode within the CSIRO
global coupled atmosphere-ocean model. In the first set we use the actual RegCM2 topography at the selected model resolutions,
which are 45, 60, 90, 120, 180, 240 and 360 km. In the second set of the experiments, the same coarse CSIRO model topography
is used in all simulations using the different resolutions of the first set. The results demonstrate that the simulation of
East Asian precipitation improves as the horizontal resolution is increased. Moreover, it is shown that the simulations using
a higher resolution along with the coarse CSIRO topography perform better than the simulations using a coarser model resolution
with corresponding model topography. This suggests that over East Asia adequate spatial resolution to resolve the physical
and dynamical processes is more important than topography. Lastly, the results indicate that model resolutions of 60 km or
higher are needed to accurately simulate the distribution of precipitation over China and East Asia. 相似文献
15.
Mladjen Ćurić Dejan Janc Katarina Veljović 《Theoretical and Applied Climatology》2010,102(3-4):471-481
Convective precipitation is the main cause of extreme rainfall events in small areas. Its primary characteristics are both large spatial and temporal variability. For this reason, the monitoring of accumulated precipitation fields (liquid and solid components) at the surface is difficult to carry out through the use of rain gauge networks or remote-sensing observations. Alternatively, numerical models seem to be the most powerful tool in simulating convective precipitation for various analyses and predictions. Due to a lack of comparisons between modelled and observed precipitation characteristics over a long period of time, we focus our research on comparisons between observations and three model samples of accumulated convective precipitation over a particular study area. We use a numerical cloud model with two model schemes involving the unified Khrgian–Mazin size distribution of cloud drops and a model scheme involving a monodisperse cloud droplet spectrum and the Marshall–Palmer size distribution for raindrops, respectively. For comparison, we have selected a study area with a sounding site. Our analysis shows that the model version with the Khrgian–Mazin size distribution exhibits a better agreement with the observed mean, median and range of extreme values of accumulated convective precipitation. Model simulations with the Khrgian–Mazin size distribution most closely match observations, with a correlation coefficient of 0.91. Use of the Marshall–Palmer size distribution, on the other hand, systemically underestimates the observed precipitation and has the lowest correlation coefficient among the methods, 0.83. Such an investigation is crucial to improve predictions of accumulated convective precipitation for various climatological and hydrological analyses and predictions. 相似文献
16.
The capability of a current state-of-the-art regional climate model for simulating the diurnal and annual cycles of rainfall over a complex subtropical region is documented here. Hourly rainfall is simulated over Southern Africa for 1998–2006 by the non-hydrostatic model weather research and forecasting (WRF), and compared to a network of 103 stations covering South Africa. We used five simulations, four of which consist of different parameterizations for atmospheric convection at a 0.5 × 0.5° resolution, performed to test the physic-dependency of the results. The fifth experiment uses explicit convection over tropical South Africa at a 1/30° resolution. WRF simulates realistic mean rainfall fields, albeit wet biases over tropical Africa. The model mean biases are strongly modulated by the convective scheme used for the simulations. The annual cycle of rainfall is well simulated over South Africa, mostly influenced by tropical summer rainfall except in the Western Cape region experiencing winter rainfall. The diurnal cycle shows a timing bias, with atmospheric convection occurring too early in the afternoon, and causing too abundant rainfall. This result, particularly true in summer over the northeastern part of the country, is weakly physic-dependent. Cloud-resolving simulations do not clearly reduce the diurnal cycle biases. In the end, the rainfall overestimations appear to be mostly imputable to the afternoon hours of the austral summer rainy season, i.e., the periods during which convective activity is intense over the region. 相似文献
17.
In atmospheric models, the partitioning of precipitation between infiltration and runoff has a major influence on the terrestrial water budget, and thereby on the simulated weather or climate. River routing models are now available to convert the simulated runoff into river discharge, offering a good opportunity to validate land surface models at the regional scale. However, given the low resolution of global atmospheric models, the quality of the hydrological simulations is much dependent on various processes occurring on unresolved spatial scales. This paper focuses on the parameterization of sub-grid hydrological processes within the ISBA land surface model. Five off-line simulations are performed over the French Rhône river basin, including various sets of parameterizations related to the sub-grid variability of topography, precipitation, maximum infiltration capacity and land surface properties. Parallel experiments are conducted at a high (8 km by 8 km) and low (1° by 1°) resolution, in order to test the robustness of the simulated water budget. Additional simulations are performed using the whole package of sub-grid parameterizations plus an exponential profile with depth of saturated hydraulic conductivity, in order to investigate the interaction between the vertical soil physics and the horizontal heterogeneities. All simulations are validated against a dense network of gauging measurements, after the simulated runoff is converted into discharge using the MODCOU river routing model. Generally speaking, the new version of ISBA, with both the sub-grid hydrology and the modified hydraulic conductivity, shows a better simulation of river discharge, as well as a weaker sensitivity to model resolution. The positive impact of each individual sub-grid parameterization on the simulated discharges is more obvious at the low resolution, whereas the high-resolution simulations are more sensitive to the exponential profile with depth of saturated hydraulic conductivity. 相似文献
18.
利用高分辨率的区域气候模式 (RegCM_NCC) 对南海夏季风爆发进行模拟研究。研究表明:该模式对积云对流参数化方案的选择十分敏感, 其中以Kuo积云参数化方案为最好, 可以比较成功地模拟出南海夏季风的爆发时间、爆发前后高、低层风场的剧烈变化以及季风与季风雨带的向北推进。然而该方案对于雨量和副热带高压位置的模拟, 与观测相比尚存在一定的偏差, 主要表现为副热带高压位置模拟偏北、偏东; 南海地区的降水量模拟偏少、降水范围偏小。此外, 采用4种参数化方案 (Kuo, Grell, MFS, Betts-Miller) 集成的结果在某种程度上要优于单个方案的结果, 这种改善主要体现在对南海地区季风爆发后降水的模拟上。 相似文献
19.
20.
分辨率对区域气候极端事件模拟的影响 总被引:13,自引:2,他引:13
利用NCAR MM5V3对1999年6月长江流域的极端异常降水事件进行了模拟,主要研究不同水平和垂直分辨率对极端区域气候事件模拟的影响。数值模拟试验表明:模式能够模拟出极端强降水的主要分布特征;水平分辨率的提高降低了模式模拟的强降水偏差,对逐日降水变化的模拟更加合理,而垂直分辨率的提高基本上也都减小了模拟的强降水过程的偏差,改善对强降水的模拟能力;模式水平、垂直分辨率的提高在一定程度上增强了对强降水过程的模拟能力。水平分辨率的提高能够改善模式对海平面气压的模拟,而垂直分辨率的提高可以改善模式模拟的地面气温和低层环流。分辨率对中层大气环流的影响不是很敏感。不同积云对流参数化方案模拟的对流降水比率随水平分辨率的变化是不同的,Grell方案对流降水比例随分辨率的提高而增加,而Kain-Fritsch方案的结果相反。 相似文献